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PDBsum entry 1aa0
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Attachment protein
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PDB id
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1aa0
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DOI no:
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Structure
5:789-798
(1997)
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PubMed id:
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Structure of bacteriophage T4 fibritin: a segmented coiled coil and the role of the C-terminal domain.
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Y.Tao,
S.V.Strelkov,
V.V.Mesyanzhinov,
M.G.Rossmann.
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ABSTRACT
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BACKGROUND: Oligomeric coiled-coil motifs are found in numerous protein
structures; among them is fibritin, a structural protein of bacteriophage T4,
which belongs to a class of chaperones that catalyze a specific phage-assembly
process. Fibritin promotes the assembly of the long tail fibers and their
subsequent attachment to the tail baseplate; it is also a sensing device that
controls the retraction of the long tail fibers in adverse environments and,
thus, prevents infection. The structure of fibritin had been predicted from
sequence and biochemical analyses to be mainly a triple-helical coiled coil. The
determination of its structure at atomic resolution was expected to give
insights into the assembly process and biological function of fibritin, and the
properties of modified coiled-coil structures in general. RESULTS: The
three-dimensional structure of fibritin E, a deletion mutant of wild-type
fibritin, was determined to 2.2 A resolution by X-ray crystallography. Three
identical subunits of 119 amino acid residues form a trimeric parallel
coiled-coil domain and a small globular C-terminal domain about a
crystallographic threefold axis. The coiled-coil domain is divided into three
segments that are separated by insertion loops. The C-terminal domain, which
consists of 30 residues from each subunit, contains a beta-propeller-like
structure with a hydrophobic interior. CONCLUSIONS: The residues within the
C-terminal domain make extensive hydrophobic and some polar intersubunit
interactions. This is consistent with the C-terminal domain being important for
the correct assembly of fibritin, as shown earlier by mutational studies. Tight
interactions between the C-terminal residues of adjacent subunits counteract the
latent instability that is suggested by the structural properties of the
coiled-coil segments. Trimerization is likely to begin with the formation of the
C-terminal domain which subsequently initiates the assembly of the coiled coil.
The interplay between the stabilizing effect of the C-terminal domain and the
labile coiled-coil domain may be essential for the fibritin function and for the
correct functioning of many other alpha-fibrous proteins.
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Selected figure(s)
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Figure 5.
Figure 5. The C-terminal domain of fibritin E. (a) Stereo
diagram of the C-terminal domain of a fibritin E subunit. The
sidechains shown are those located in the hydrophobic interior
formed at the interface between three symmetry-related subunits.
The vertical line shows the trimer axis. Atoms are shown in
standard colors. (b) Ribbon diagram of the C-terminal domain
looking along the trimer axis, each subunit is shown in a
different color. (c) Mainchain hydrogen bonds formed within the
C-terminal domain of a fibritin E trimer. Parts (a) and (b) were
drawn with MOLSCRIPT [43] and RASTER3D [44].
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The above figure is
reprinted
by permission from Cell Press:
Structure
(1997,
5,
789-798)
copyright 1997.
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Figure was
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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E.C.Schulz,
and
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Curr Opin Struct Biol,
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(2011).
Dual modification of a triple-stranded β-helix nanotube with Ru and Re metal complexes to promote photocatalytic reduction of CO(2).
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Chem Commun (Camb),
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J.S.McLellan,
M.Chen,
A.Kim,
Y.Yang,
B.S.Graham,
and
P.D.Kwong
(2010).
Structural basis of respiratory syncytial virus neutralization by motavizumab.
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Nat Struct Mol Biol,
17,
248-250.
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PDB code:
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N.Yokoi,
H.Inaba,
M.Terauchi,
A.Z.Stieg,
N.J.Sanghamitra,
T.Koshiyama,
K.Yutani,
S.Kanamaru,
F.Arisaka,
T.Hikage,
A.Suzuki,
T.Yamane,
J.K.Gimzewski,
Y.Watanabe,
S.Kitagawa,
and
T.Ueno
(2010).
Construction of robust bio-nanotubes using the controlled self-assembly of component proteins of bacteriophage T4.
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Small,
6,
1873-1879.
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PDB code:
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P.G.Leiman,
F.Arisaka,
M.J.van Raaij,
V.A.Kostyuchenko,
A.A.Aksyuk,
S.Kanamaru,
and
M.G.Rossmann
(2010).
Morphogenesis of the T4 tail and tail fibers.
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Virol J,
7,
355.
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A.Bhardwaj,
N.Walker-Kopp,
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and
G.Cingolani
(2009).
An evolutionarily conserved family of virion tail needles related to bacteriophage P22 gp26: correlation between structural stability and length of the alpha-helical trimeric coiled coil.
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J Mol Biol,
391,
227-245.
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P.Guardado-Calvo,
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A.L.Llamas-Saiz,
and
M.J.van Raaij
(2009).
Crystallographic structure of the {alpha}-helical triple coiled-coil domain of avian reovirus S1133 fibre.
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J Gen Virol,
90,
672-677.
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PDB codes:
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A.Bhardwaj,
N.Walker-Kopp,
S.Wilkens,
and
G.Cingolani
(2008).
Foldon-guided self-assembly of ultra-stable protein fibers.
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Protein Sci,
17,
1475-1485.
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C.Boulègue,
H.J.Musiol,
M.G.Götz,
C.Renner,
and
L.Moroder
(2008).
Natural and artificial cystine knots for assembly of homo- and heterotrimeric collagen models.
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Antioxid Redox Signal,
10,
113-126.
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C.Du,
M.Wang,
J.Liu,
M.Pan,
Y.Cai,
and
J.Yao
(2008).
Improvement of thermostability of recombinant collagen-like protein by incorporating a foldon sequence.
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Appl Microbiol Biotechnol,
79,
195-202.
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K.H.Choi,
J.McPartland,
I.Kaganman,
V.D.Bowman,
L.B.Rothman-Denes,
and
M.G.Rossmann
(2008).
Insight into DNA and protein transport in double-stranded DNA viruses: the structure of bacteriophage N4.
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J Mol Biol,
378,
726-736.
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R.Conners,
D.J.Hill,
E.Borodina,
C.Agnew,
S.J.Daniell,
N.M.Burton,
R.B.Sessions,
A.R.Clarke,
L.E.Catto,
D.Lammie,
T.Wess,
R.L.Brady,
and
M.Virji
(2008).
The Moraxella adhesin UspA1 binds to its human CEACAM1 receptor by a deformable trimeric coiled-coil.
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EMBO J,
27,
1779-1789.
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PDB code:
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D.Schwarzer,
K.Stummeyer,
R.Gerardy-Schahn,
and
M.Mühlenhoff
(2007).
Characterization of a novel intramolecular chaperone domain conserved in endosialidases and other bacteriophage tail spike and fiber proteins.
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J Biol Chem,
282,
2821-2831.
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J.E.Johnson,
and
W.Chiu
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DNA packaging and delivery machines in tailed bacteriophages.
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Curr Opin Struct Biol,
17,
237-243.
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R.Sapinoro,
C.A.Maguire,
A.Burgess,
and
S.Dewhurst
(2007).
Enhanced transduction of dendritic cells by FcgammaRI-targeted adenovirus vectors.
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J Gene Med,
9,
1033-1045.
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D.H.Shin,
J.S.Kim,
H.Yokota,
R.Kim,
and
S.H.Kim
(2006).
Crystal structure of the DUF16 domain of MPN010 from Mycoplasma pneumoniae.
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Protein Sci,
15,
921-928.
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PDB code:
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S.Raman,
G.Machaidze,
A.Lustig,
U.Aebi,
and
P.Burkhard
(2006).
Structure-based design of peptides that self-assemble into regular polyhedral nanoparticles.
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Nanomedicine,
2,
95.
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S.Spinelli,
V.Campanacci,
S.Blangy,
S.Moineau,
M.Tegoni,
and
C.Cambillau
(2006).
Modular structure of the receptor binding proteins of Lactococcus lactis phages. The RBP structure of the temperate phage TP901-1.
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J Biol Chem,
281,
14256-14262.
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PDB code:
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F.Arisaka
(2005).
Assembly and infection process of bacteriophage T4.
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Chaos,
15,
047502.
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L.Tang,
W.R.Marion,
G.Cingolani,
P.E.Prevelige,
and
J.E.Johnson
(2005).
Three-dimensional structure of the bacteriophage P22 tail machine.
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EMBO J,
24,
2087-2095.
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V.A.Kostyuchenko,
P.R.Chipman,
P.G.Leiman,
F.Arisaka,
V.V.Mesyanzhinov,
and
M.G.Rossmann
(2005).
The tail structure of bacteriophage T4 and its mechanism of contraction.
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Nat Struct Mol Biol,
12,
810-813.
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PDB codes:
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J.Engel
(2004).
Role of oligomerization domains in thrombospondins and other extracellular matrix proteins.
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Int J Biochem Cell Biol,
36,
997.
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J.F.Bower,
X.Yang,
J.Sodroski,
and
T.M.Ross
(2004).
Elicitation of neutralizing antibodies with DNA vaccines expressing soluble stabilized human immunodeficiency virus type 1 envelope glycoprotein trimers conjugated to C3d.
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J Virol,
78,
4710-4719.
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K.Papanikolopoulou,
V.Forge,
P.Goeltz,
and
A.Mitraki
(2004).
Formation of highly stable chimeric trimers by fusion of an adenovirus fiber shaft fragment with the foldon domain of bacteriophage t4 fibritin.
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J Biol Chem,
279,
8991-8998.
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P.G.Leiman,
P.R.Chipman,
V.A.Kostyuchenko,
V.V.Mesyanzhinov,
and
M.G.Rossmann
(2004).
Three-dimensional rearrangement of proteins in the tail of bacteriophage T4 on infection of its host.
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Cell,
118,
419-429.
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PDB code:
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V.V.Mesyanzhinov,
P.G.Leiman,
V.A.Kostyuchenko,
L.P.Kurochkina,
K.A.Miroshnikov,
N.N.Sykilinda,
and
M.M.Shneider
(2004).
Molecular architecture of bacteriophage T4.
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Biochemistry (Mosc),
69,
1190-1202.
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J.Stetefeld,
S.Frank,
M.Jenny,
T.Schulthess,
R.A.Kammerer,
S.Boudko,
R.Landwehr,
K.Okuyama,
and
J.Engel
(2003).
Collagen stabilization at atomic level: crystal structure of designed (GlyProPro)10foldon.
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Structure,
11,
339-346.
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PDB code:
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O.Pakkanen,
E.R.Hämäläinen,
K.I.Kivirikko,
and
J.Myllyharju
(2003).
Assembly of stable human type I and III collagen molecules from hydroxylated recombinant chains in the yeast Pichia pastoris. Effect of an engineered C-terminal oligomerization domain foldon.
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J Biol Chem,
278,
32478-32483.
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P.R.Weigele,
E.Scanlon,
and
J.King
(2003).
Homotrimeric, beta-stranded viral adhesins and tail proteins.
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J Bacteriol,
185,
4022-4030.
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S.V.Strelkov,
H.Herrmann,
and
U.Aebi
(2003).
Molecular architecture of intermediate filaments.
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Bioessays,
25,
243-251.
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A.McAlinden,
E.C.Crouch,
J.G.Bann,
P.Zhang,
and
L.J.Sandell
(2002).
Trimerization of the amino propeptide of type IIA procollagen using a 14-amino acid sequence derived from the coiled-coil neck domain of surfactant protein D.
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J Biol Chem,
277,
41274-41281.
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S.P.Boudko,
Y.Y.Londer,
A.V.Letarov,
N.V.Sernova,
J.Engel,
and
V.V.Mesyanzhinov
(2002).
Domain organization, folding and stability of bacteriophage T4 fibritin, a segmented coiled-coil protein.
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Eur J Biochem,
269,
833-841.
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S.V.Strelkov,
H.Herrmann,
N.Geisler,
T.Wedig,
R.Zimbelmann,
U.Aebi,
and
P.Burkhard
(2002).
Conserved segments 1A and 2B of the intermediate filament dimer: their atomic structures and role in filament assembly.
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EMBO J,
21,
1255-1266.
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PDB codes:
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M.J.van Raaij,
G.Schoehn,
M.Jaquinod,
K.Ashman,
M.R.Burda,
and
S.Miller
(2001).
Identification and crystallisation of a heat- and protease-stable fragment of the bacteriophage T4 short tail fibre.
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Biol Chem,
382,
1049-1055.
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V.Krasnykh,
N.Belousova,
N.Korokhov,
G.Mikheeva,
and
D.T.Curiel
(2001).
Genetic targeting of an adenovirus vector via replacement of the fiber protein with the phage T4 fibritin.
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J Virol,
75,
4176-4183.
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M.G.Rossmann
(2000).
Fitting atomic models into electron-microscopy maps.
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Acta Crystallogr D Biol Crystallogr,
56,
1341-1349.
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L.Liljas
(1999).
Virus assembly.
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Curr Opin Struct Biol,
9,
129-134.
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R.A.Kammerer,
T.Schulthess,
R.Landwehr,
B.Schumacher,
A.Lustig,
P.D.Yurchenco,
M.A.Ruegg,
J.Engel,
and
A.J.Denzer
(1999).
Interaction of agrin with laminin requires a coiled-coil conformation of the agrin-binding site within the laminin gamma1 chain.
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EMBO J,
18,
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R.Peteranderl,
M.Rabenstein,
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C.W.Liu,
D.E.Wemmer,
D.S.King,
and
H.C.Nelson
(1999).
Biochemical and biophysical characterization of the trimerization domain from the heat shock transcription factor.
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Biochemistry,
38,
3559-3569.
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V.A.Kostyuchenko,
G.A.Navruzbekov,
L.P.Kurochkina,
S.V.Strelkov,
V.V.Mesyanzhinov,
and
M.G.Rossmann
(1999).
The structure of bacteriophage T4 gene product 9: the trigger for tail contraction.
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Structure,
7,
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PDB codes:
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J.J.Rux,
and
R.M.Burnett
(1998).
Spherical viruses.
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Curr Opin Struct Biol,
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J.P.Schneider,
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and
W.F.DeGrado
(1998).
Analysis and design of three-stranded coiled coils and three-helix bundles.
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Fold Des,
3,
R29-R40.
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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
code is
shown on the right.
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Links
