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PDBsum entry 1q5c
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Structural protein
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PDB id
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1q5c
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Contents |
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* Residue conservation analysis
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DOI no:
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Science
302:109-113
(2003)
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PubMed id:
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Untangling desmosomal knots with electron tomography.
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W.He,
P.Cowin,
D.L.Stokes.
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ABSTRACT
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Cell adhesion by adherens junctions and desmosomes relies on interactions
between cadherin molecules. However, the molecular interfaces that define
molecular specificity and that mediate adhesion remain controversial. We used
electron tomography of plastic sections from neonatal mouse skin to visualize
the organization of desmosomes in situ. The resulting three-dimensional maps
reveal individual cadherin molecules forming discrete groups and interacting
through their tips. Fitting of an x-ray crystal structure for C-cadherin to
these maps is consistent with a flexible intermolecular interface mediated by an
exchange of amino-terminal tryptophans. This flexibility suggests a novel
mechanism for generating both cis and trans interactions and for propagating
these adhesive interactions along the junction.
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Selected figure(s)
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Figure 1.
Fig. 1. Images of desmosomes from neonatal mouse epidermis. (A)
Low-magnification image showing an irregular border between
keratinocytes coupled by frequent desmosomes. This region of the
cell contains many ribosomes but, if the opaque discs are
construed as en face views of desmosomes, lacks organelles. (B
to D) Higher magnification images reveal the typical lamellar
structure of desmosomes. The membrane appears as a narrow white
zone; cadherin molecules appear as strands crossing the
extracellular space, which is bisected by an electron-dense
midline. Individual cadherins are difficult to identify because
of extensive superposition of these densely packed molecules
within the section; individual molecules are more readily seen
in ultrathin sections that are unsuitable for tomography but are
included in (13). A very dense plaque abuts the intracellular
face of the membrane and leads to a looser network of fibrous
densities that ultimately connect to bundles of intermediate
filaments. (E and F) Sections through the tomographic
reconstruction of desmosome "R" (see Table 1) cut parallel (E)
and perpendicular (F) to the untilted sample [e.g., (B)]. The
membrane is outlined in red, cadherin molecules in blue, two
zones of the cytoplasmic plaque in orange and light green, and
intermediate filaments in dark green. The perpendicular section
in (F) reveals the thickness of the plastic section and
illustrates that the resolution was quite isotropic [see also
(13)]. Scale bars, 500 nm (A), 100 nm [(B) to (D)], 30 nm [(E)
and (F)].
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Figure 2.
Fig. 2. Delineation and fitting of cadherin molecules to the
desmosome. With the C-cadherin x-ray structure as a template,
136 cadherin molecules were delineated in the region of
desmosome "P" (see Table 1). (A) Densities from the map, with
individual cadherin molecules in various colors and the membrane
in cyan. (B) A representative group of cadherin molecules
clustering at the midline and interacting predominantly at their
tips. (C to E) Three recurrent molecular interactions within the
molecular groups, referred to as W, S, and  , respectively.
The x-ray structure for C-cadherin was fitted as a rigid body
with no changes within the structure itself. (G to I) The
resulting juxtaposition of EC1 domains, where each molecule has
a distinct ribbon color, calcium ions are brown, the
space-filling representation of the Trp2 side chain is dark
orange, and the HAV sequence has a light orange ribbon with
stick-like side chains.
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The above figures are
reprinted
by permission from the AAAs:
Science
(2003,
302,
109-113)
copyright 2003.
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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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A.Al-Amoudi,
D.Castaño-Diez,
D.P.Devos,
R.B.Russell,
G.T.Johnson,
and
A.S.Frangakis
(2011).
The three-dimensional molecular structure of the desmosomal plaque.
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Proc Natl Acad Sci U S A,
108,
6480-6485.
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A.Nans,
S.Einheber,
J.L.Salzer,
and
D.L.Stokes
(2011).
Electron tomography of paranodal septate-like junctions and the associated axonal and glial cytoskeletons in the central nervous system.
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J Neurosci Res,
89,
310-319.
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C.L.Lawson,
M.L.Baker,
C.Best,
C.Bi,
M.Dougherty,
P.Feng,
G.van Ginkel,
B.Devkota,
I.Lagerstedt,
S.J.Ludtke,
R.H.Newman,
T.J.Oldfield,
I.Rees,
G.Sahni,
R.Sala,
S.Velankar,
J.Warren,
J.D.Westbrook,
K.Henrick,
G.J.Kleywegt,
H.M.Berman,
and
W.Chiu
(2011).
EMDataBank.org: unified data resource for CryoEM.
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Nucleic Acids Res,
39,
D456-D464.
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A.Pertsinidis,
Y.Zhang,
and
S.Chu
(2010).
Subnanometre single-molecule localization, registration and distance measurements.
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Nature,
466,
647-651.
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C.K.Fung,
K.Seiffert-Sinha,
K.W.Lai,
R.Yang,
D.Panyard,
J.Zhang,
N.Xi,
and
A.A.Sinha
(2010).
Investigation of human keratinocyte cell adhesion using atomic force microscopy.
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Nanomedicine,
6,
191-200.
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D.Garrod
(2010).
Desmosomes in vivo.
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Dermatol Res Pract,
2010,
212439.
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G.R.Owen,
and
D.L.Stokes
(2010).
Exploring the Nature of Desmosomal Cadherin Associations in 3D.
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Dermatol Res Pract,
2010,
930401.
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K.J.Green,
S.Getsios,
S.Troyanovsky,
and
L.M.Godsel
(2010).
Intercellular junction assembly, dynamics, and homeostasis.
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Cold Spring Harb Perspect Biol,
2,
a000125.
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L.A.Chtcheglova,
L.Wildling,
J.Waschke,
D.Drenckhahn,
and
P.Hinterdorfer
(2010).
AFM functional imaging on vascular endothelial cells.
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J Mol Recognit,
23,
589-596.
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O.J.Harrison,
F.Bahna,
P.S.Katsamba,
X.Jin,
J.Brasch,
J.Vendome,
G.Ahlsen,
K.J.Carroll,
S.R.Price,
B.Honig,
and
L.Shapiro
(2010).
Two-step adhesive binding by classical cadherins.
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Nat Struct Mol Biol,
17,
348-357.
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PDB codes:
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T.J.Harris,
and
U.Tepass
(2010).
Adherens junctions: from molecules to morphogenesis.
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Nat Rev Mol Cell Biol,
11,
502-514.
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Y.Wu,
X.Jin,
O.Harrison,
L.Shapiro,
B.H.Honig,
and
A.Ben-Shaul
(2010).
Cooperativity between trans and cis interactions in cadherin-mediated junction formation.
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Proc Natl Acad Sci U S A,
107,
17592-17597.
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A.A.Sousa,
M.F.Hohmann-Marriott,
G.Zhang,
and
R.D.Leapman
(2009).
Monte Carlo electron-trajectory simulations in bright-field and dark-field STEM: implications for tomography of thick biological sections.
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Ultramicroscopy,
109,
213-221.
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K.Zheng,
J.S.Laurence,
K.Kuczera,
G.Verkhivker,
C.R.Middaugh,
and
T.J.Siahaan
(2009).
Characterization of multiple stable conformers of the EC5 domain of E-cadherin and the interaction of EC5 with E-cadherin peptides.
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Chem Biol Drug Des,
73,
584-598.
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L.Shapiro,
and
W.I.Weis
(2009).
Structure and biochemistry of cadherins and catenins.
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Cold Spring Harbor Perspect Biol,
1,
a003053.
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M.L.Dustin
(2009).
Supported bilayers at the vanguard of immune cell activation studies.
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J Struct Biol,
168,
152-160.
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M.Trivedi,
R.A.Davis,
Y.Shabaik,
A.Roy,
G.Verkhivker,
J.S.Laurence,
C.R.Middaugh,
and
T.J.Siahaan
(2009).
The role of covalent dimerization on the physical and chemical stability of the EC1 domain of human E-cadherin.
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J Pharm Sci,
98,
3562-3574.
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P.Hulpiau,
and
F.van Roy
(2009).
Molecular evolution of the cadherin superfamily.
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Int J Biochem Cell Biol,
41,
349-369.
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W.M.Heupel,
T.Müller,
A.Efthymiadis,
E.Schmidt,
D.Drenckhahn,
and
J.Waschke
(2009).
Peptides Targeting the Desmoglein 3 Adhesive Interface Prevent Autoantibody-induced Acantholysis in Pemphigus.
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J Biol Chem,
284,
8589-8595.
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X.Mao,
E.J.Choi,
and
A.S.Payne
(2009).
Disruption of desmosome assembly by monovalent human pemphigus vulgaris monoclonal antibodies.
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J Invest Dermatol,
129,
908-918.
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Y.Zhang,
S.Sivasankar,
W.J.Nelson,
and
S.Chu
(2009).
Resolving cadherin interactions and binding cooperativity at the single-molecule level.
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Proc Natl Acad Sci U S A,
106,
109-114.
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Y.Zhang,
Y.Zhou,
J.Zhu,
S.Dong,
C.Li,
and
Q.Xiang
(2009).
Effect of a novel recombinant protein of fibronectinIII7-10/cadherin 11 EC1-2 on osteoblastic adhesion and differentiation.
|
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Biosci Biotechnol Biochem,
73,
1999-2006.
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D.Acehan,
C.Petzold,
I.Gumper,
D.D.Sabatini,
E.J.Müller,
P.Cowin,
and
D.L.Stokes
(2008).
Plakoglobin is required for effective intermediate filament anchorage to desmosomes.
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J Invest Dermatol,
128,
2665-2675.
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D.Studer,
B.M.Humbel,
and
M.Chiquet
(2008).
Electron microscopy of high pressure frozen samples: bridging the gap between cellular ultrastructure and atomic resolution.
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Histochem Cell Biol,
130,
877-889.
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E.Salvi,
F.Cantele,
L.Zampighi,
N.Fain,
G.Pigino,
G.Zampighi,
and
S.Lanzavecchia
(2008).
JUST (Java User Segmentation Tool) for semi-automatic segmentation of tomographic maps.
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J Struct Biol,
161,
287-297.
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M.Auer,
A.J.Koster,
U.Ziese,
C.Bajaj,
N.Volkmann,
d.a. .N.Wang,
and
A.J.Hudspeth
(2008).
Three-dimensional architecture of hair-bundle linkages revealed by electron-microscopic tomography.
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J Assoc Res Otolaryngol,
9,
215-224.
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M.Sotomayor,
and
K.Schulten
(2008).
The allosteric role of the Ca2+ switch in adhesion and elasticity of C-cadherin.
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Biophys J,
94,
4621-4633.
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O.Milstein,
S.Y.Tseng,
T.Starr,
J.Llodra,
A.Nans,
M.Liu,
M.K.Wild,
P.A.van der Merwe,
D.L.Stokes,
Y.Reisner,
and
M.L.Dustin
(2008).
Nanoscale increases in CD2-CD48-mediated intermembrane spacing decrease adhesion and reorganize the immunological synapse.
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J Biol Chem,
283,
34414-34422.
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P.Berkowitz,
M.Chua,
Z.Liu,
L.A.Diaz,
and
D.S.Rubenstein
(2008).
Autoantibodies in the autoimmune disease pemphigus foliaceus induce blistering via p38 mitogen-activated protein kinase-dependent signaling in the skin.
|
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Am J Pathol,
173,
1628-1636.
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S.Jonić,
C.O.Sorzano,
and
N.Boisset
(2008).
Comparison of single-particle analysis and electron tomography approaches: an overview.
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J Microsc,
232,
562-579.
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S.Posy,
L.Shapiro,
and
B.Honig
(2008).
Sequence and structural determinants of strand swapping in cadherin domains: do all cadherins bind through the same adhesive interface?
|
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J Mol Biol,
378,
954-968.
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V.Z.Miloushev,
F.Bahna,
C.Ciatto,
G.Ahlsen,
B.Honig,
L.Shapiro,
and
A.G.Palmer
(2008).
Dynamic properties of a type II cadherin adhesive domain: implications for the mechanism of strand-swapping of classical cadherins.
|
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Structure,
16,
1195-1205.
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W.He,
M.S.Ladinsky,
K.E.Huey-Tubman,
G.J.Jensen,
J.R.McIntosh,
and
P.J.Björkman
(2008).
FcRn-mediated antibody transport across epithelial cells revealed by electron tomography.
|
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Nature,
455,
542-546.
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W.Zhao,
D.E.Moilanen,
E.E.Fenn,
and
M.D.Fayer
(2008).
Water at the surfaces of aligned phospholipid multibilayer model membranes probed with ultrafast vibrational spectroscopy.
|
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J Am Chem Soc,
130,
13927-13937.
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Z.M.Ahmed,
S.Riazuddin,
S.Aye,
R.A.Ali,
H.Venselaar,
S.Anwar,
P.P.Belyantseva,
M.Qasim,
S.Riazuddin,
and
T.B.Friedman
(2008).
Gene structure and mutant alleles of PCDH15: nonsyndromic deafness DFNB23 and type 1 Usher syndrome.
|
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Hum Genet,
124,
215-223.
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A.Al-Amoudi,
D.C.Díez,
M.J.Betts,
and
A.S.Frangakis
(2007).
The molecular architecture of cadherins in native epidermal desmosomes.
|
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Nature,
450,
832-837.
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A.R.Aricescu,
C.Siebold,
K.Choudhuri,
V.T.Chang,
W.Lu,
S.J.Davis,
P.A.van der Merwe,
and
E.Y.Jones
(2007).
Structure of a tyrosine phosphatase adhesive interaction reveals a spacer-clamp mechanism.
|
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Science,
317,
1217-1220.
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PDB code:
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D.L.Stokes
(2007).
Desmosomes from a structural perspective.
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Curr Opin Cell Biol,
19,
565-571.
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E.Parisini,
J.M.Higgins,
J.H.Liu,
M.B.Brenner,
and
J.H.Wang
(2007).
The crystal structure of human E-cadherin domains 1 and 2, and comparison with other cadherins in the context of adhesion mechanism.
|
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J Mol Biol,
373,
401-411.
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PDB code:
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F.Cantele,
L.Zampighi,
M.Radermacher,
G.Zampighi,
and
S.Lanzavecchia
(2007).
Local refinement: an attempt to correct for shrinkage and distortion in electron tomography.
|
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J Struct Biol,
158,
59-70.
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J.Engel
(2007).
Visions for novel biophysical elucidations of extracellular matrix networks.
|
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Int J Biochem Cell Biol,
39,
311-318.
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J.Waschke,
C.Menendez-Castro,
P.Bruggeman,
R.Koob,
M.Amagai,
H.J.Gruber,
D.Drenckhahn,
and
W.Baumgartner
(2007).
Imaging and force spectroscopy on desmoglein 1 using atomic force microscopy reveal multivalent Ca(2+)-dependent, low-affinity trans-interaction.
|
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J Membr Biol,
216,
83-92.
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L.Shapiro,
J.Love,
and
D.R.Colman
(2007).
Adhesion molecules in the nervous system: structural insights into function and diversity.
|
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Annu Rev Neurosci,
30,
451-474.
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S.Pokutta,
and
W.I.Weis
(2007).
Structure and mechanism of cadherins and catenins in cell-cell contacts.
|
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Annu Rev Cell Dev Biol,
23,
237-261.
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W.He,
C.Kivork,
S.Machinani,
M.K.Morphew,
A.M.Gail,
D.B.Tesar,
N.E.Tiangco,
J.R.McIntosh,
and
P.J.Bjorkman
(2007).
A freeze substitution fixation-based gold enlarging technique for EM studies of endocytosed Nanogold-labeled molecules.
|
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J Struct Biol,
160,
103-113.
|
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A.M.Craig,
E.R.Graf,
and
M.W.Linhoff
(2006).
How to build a central synapse: clues from cell culture.
|
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Trends Neurosci,
29,
8.
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D.Leckband,
and
A.Prakasam
(2006).
Mechanism and dynamics of cadherin adhesion.
|
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Annu Rev Biomed Eng,
8,
259-287.
|
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F.Cailliez,
and
R.Lavery
(2006).
Dynamics and stability of E-cadherin dimers.
|
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Biophys J,
91,
3964-3971.
|
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O.Thoumine,
M.Lambert,
R.M.Mège,
and
D.Choquet
(2006).
Regulation of N-cadherin dynamics at neuronal contacts by ligand binding and cytoskeletal coupling.
|
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Mol Biol Cell,
17,
862-875.
|
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P.John,
M.Tariq,
M.Arshad Rafiq,
M.Amin-Ud-Din,
D.Muhammad,
I.Waheed,
M.Ansar,
and
W.Ahmad
(2006).
Recurrent intragenic deletion mutation in desmoglein 4 gene underlies autosomal recessive hypotrichosis in two Pakistani families of Balochi and Sindhi origins.
|
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Arch Dermatol Res,
298,
135-137.
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S.D.Patel,
C.Ciatto,
C.P.Chen,
F.Bahna,
M.Rajebhosale,
N.Arkus,
I.Schieren,
T.M.Jessell,
B.Honig,
S.R.Price,
and
L.Shapiro
(2006).
Type II cadherin ectodomain structures: implications for classical cadherin specificity.
|
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Cell,
124,
1255-1268.
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PDB codes:
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Z.Lin,
S.Sriskanthadevan,
H.Huang,
C.H.Siu,
and
D.Yang
(2006).
Solution structures of the adhesion molecule DdCAD-1 reveal new insights into Ca(2+)-dependent cell-cell adhesion.
|
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Nat Struct Mol Biol,
13,
1016-1022.
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PDB codes:
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A.Al-Amoudi,
J.Dubochet,
and
L.Norlén
(2005).
Nanostructure of the epidermal extracellular space as observed by cryo-electron microscopy of vitreous sections of human skin.
|
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J Invest Dermatol,
124,
764-777.
|
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A.Shimizu,
A.Ishiko,
T.Ota,
H.Saito,
H.Oka,
K.Tsunoda,
M.Amagai,
and
T.Nishikawa
(2005).
In vivo ultrastructural localization of the desmoglein 3 adhesive interface to the desmosome mid-line.
|
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J Invest Dermatol,
124,
984-989.
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B.M.Gumbiner
(2005).
Regulation of cadherin-mediated adhesion in morphogenesis.
|
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Nat Rev Mol Cell Biol,
6,
622-634.
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P.Lupetti,
S.Lanzavecchia,
D.Mercati,
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Three-dimensional reconstruction of axonemal outer dynein arms in situ by electron tomography.
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Cell Motil Cytoskeleton,
62,
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R.McIntosh,
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(2005).
New views of cells in 3D: an introduction to electron tomography.
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Trends Cell Biol,
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V.Lucić,
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Structural studies by electron tomography: from cells to molecules.
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Annu Rev Biochem,
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A.Al-Amoudi,
J.J.Chang,
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D.Studer,
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Cryo-electron microscopy of vitreous sections.
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EMBO J,
23,
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A.W.Koch,
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(2004).
Structure of the neural (N-) cadherin prodomain reveals a cadherin extracellular domain-like fold without adhesive characteristics.
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Structure,
12,
793-805.
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PDB code:
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C.Moss,
A.Martinez-Mir,
H.Lam,
M.Tadin-Strapps,
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A recurrent intragenic deletion in the desmoglein 4 gene underlies localized autosomal recessive hypotrichosis.
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J Invest Dermatol,
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D.Häussinger,
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Proteolytic E-cadherin activation followed by solution NMR and X-ray crystallography.
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EMBO J,
23,
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PDB code:
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E.Perret,
A.Leung,
H.Feracci,
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Trans-bonded pairs of E-cadherin exhibit a remarkable hierarchy of mechanical strengths.
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Proc Natl Acad Sci U S A,
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The cadherin-catenin complex as a focal point of cell adhesion and signalling: new insights from three-dimensional structures.
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Classical cadherin adhesion molecules: coordinating cell adhesion, signaling and the cytoskeleton.
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Coordinated expression of desmoglein 1 and desmocollin 1 regulates intercellular adhesion.
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T.Yin,
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Cell adhesion and signalling by cadherins and Ig-CAMs in cancer.
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Cadherin-mediated cell-cell adhesion: sticking together as a family.
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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
codes are
shown on the right.
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Links
