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* Residue conservation analysis
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PDB id:
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Peptide binding protein
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Title:
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Crystal structure of the shank pdz-ligand complex reveals a class i pdz interaction and a novel pdz-pdz dimerization
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Structure:
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Shank1. Chain: a, b. Fragment: pdz domain. Engineered: yes. C-terminal hexapeptide from guanylate kinase-associated protein. Chain: c, d. Synonym: c-terminal hexapeptide from gkap. Engineered: yes
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Source:
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Rattus norvegicus. Norway rat. Organism_taxid: 10116. Gene: shank1. Expressed in: escherichia coli bl21(de3). Expression_system_taxid: 469008. Synthetic: yes. Other_details: eaqtrl sequence is thE C-terminal hexapeptide of gkap protein in rattus norvegicus
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Biol. unit:
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Dimer (from
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Resolution:
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2.25Å
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R-factor:
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0.251
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R-free:
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0.280
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Authors:
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Y.J.Im,J.H.Lee,S.H.Park,S.J.Park,S.-H.Rho,G.B.Kang,E.Kim,S.H.Eom
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Key ref:
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Y.J.Im
et al.
(2003).
Crystal structure of the Shank PDZ-ligand complex reveals a class I PDZ interaction and a novel PDZ-PDZ dimerization.
J Biol Chem,
278,
48099-48104.
PubMed id:
DOI:
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Date:
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31-Jul-03
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Release date:
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27-Jan-04
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PROCHECK
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Headers
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References
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Enzyme class:
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Chains A, B:
E.C.?
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DOI no:
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J Biol Chem
278:48099-48104
(2003)
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PubMed id:
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Crystal structure of the Shank PDZ-ligand complex reveals a class I PDZ interaction and a novel PDZ-PDZ dimerization.
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Y.J.Im,
J.H.Lee,
S.H.Park,
S.J.Park,
S.H.Rho,
G.B.Kang,
E.Kim,
S.H.Eom.
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ABSTRACT
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The Shank/proline-rich synapse-associated protein family of multidomain proteins
is known to play an important role in the organization of synaptic multiprotein
complexes. For instance, the Shank PDZ domain binds to the C termini of
guanylate kinase-associated proteins, which in turn interact with the guanylate
kinase domain of postsynaptic density-95 scaffolding proteins. Here we describe
the crystal structures of Shank1 PDZ in its peptide free form and in complex
with the C-terminal hexapeptide (EAQTRL) of guanylate kinase-associated protein
(GKAP1a) determined at 1.8- and 2.25-A resolutions, respectively. The structure
shows the typical class I PDZ interaction of PDZ-peptide complex with the
consensus sequence -X-(Thr/Ser)-X-Leu. In addition, Asp-634 within the Shank1
PDZ domain recognizes the positively charged Arg at -1 position and hydrogen
bonds, and salt bridges between Arg-607 and the side chains of the ligand at -3
and -5 positions contribute further to the recognition of the peptide ligand.
Remarkably, whether free or complexed, Shank1 PDZ domains form dimers with a
conserved beta B/beta C loop and N-terminal beta A strands, suggesting a novel
model of PDZ-PDZ homodimerization. This implies that antiparallel dimerization
through the N-terminal beta A strands could be a common configuration among PDZ
dimers. Within the dimeric structure, the two-peptide binding sites are arranged
so that the N termini of the bound peptide ligands are in close proximity and
oriented toward the 2-fold axis of the dimer. This configuration may provide a
means of facilitating dimeric organization of PDZ-target assemblies.
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Selected figure(s)
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Figure 1.
FIG. 1. Structure of the SHANK1 PDZ domain. A, stereoview
of a ribbon diagram showing the monomeric structure of the Shank
PDZ-ligand complex. The  -strands are labeled
A-
F,
and the  -helices are labeled
A
and B. The ligand is
colored dark gray. The dotted line indicates a disordered loop
(residues 610-614) that is not seen in peptide-bound structure.
All of the residues in the loop were observed in peptide-free
structure. B, amino acid sequence alignment of the PDZ domains
from the rat and human Shank family, human NHERF (37), rat PSD95
(26), and rat GRIP1 (35). The sequences were aligned using the
program ClustalX (38). Highly conserved residues are shaded in
black and gray. The secondary structure elements of Shank1 PDZ
are shown as arrows ( -strands), bars ( -helices), and lines
(connecting loops). C, superposition of the PDZ domains. Black
ribbon indicates Shank1 PDZ domain. Light and dark gray ribbons
indicate PDZ domains of human NHERF (Protein Data Bank code 1G9O
[PDB]
) and rat PSD95 (Protein Data Bank code 1BFE [PDB]
), respectively.
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Figure 3.
FIG. 3. Overall structures of the PDZ dimer. A, Shank1 PDZ
dimer. The black arrow indicates the N-terminal end of each
peptide ligand. B, ribbon diagram of the GRIP PDZ6 dimer
(Protein Data Bank code 1N7F [PDB]
). C, Shank PDZ dimer interface. Side chains of hydrophobic
residues at the interface are shown as ball and stick models. D,
amino acid sequence and predicted secondary structure of the
C-terminal domain of PIX. The secondary
structure was predicted using the PredictProtein Web server
(cubic.bioc.columbia.edu/predictprotein/). E, proposed model of
the Shank1 PDZ and PIX C terminus complex.
The figures were made using PyMOL (www.pymol.org).
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The above figures are
reprinted
by permission from the ASBMB:
J Biol Chem
(2003,
278,
48099-48104)
copyright 2003.
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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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J.H.Lee,
H.Park,
S.J.Park,
H.J.Kim,
and
S.H.Eom
(2011).
The structural flexibility of the shank1 PDZ domain is important for its binding to different ligands.
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Biochem Biophys Res Commun,
407,
207-212.
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PDB codes:
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H.J.Lee,
and
J.J.Zheng
(2010).
PDZ domains and their binding partners: structure, specificity, and modification.
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Cell Commun Signal,
8,
8.
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O.Sakarya,
C.Conaco,
O.Egecioglu,
S.A.Solla,
T.H.Oakley,
and
K.S.Kosik
(2010).
Evolutionary expansion and specialization of the PDZ domains.
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Mol Biol Evol,
27,
1058-1069.
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W.S.Iskenderian-Epps,
and
B.Imperiali
(2010).
Modulation of Shank3 PDZ domain ligand-binding affinity by dimerization.
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Chembiochem,
11,
1979-1984.
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D.Sengupta,
S.Truschel,
C.Bachert,
and
A.D.Linstedt
(2009).
Organelle tethering by a homotypic PDZ interaction underlies formation of the Golgi membrane network.
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J Cell Biol,
186,
41-55.
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H.Chen,
S.Tong,
X.Li,
J.Wu,
Z.Zhu,
L.Niu,
and
M.Teng
(2009).
Structure of the second PDZ domain from human zonula occludens 2.
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Acta Crystallogr Sect F Struct Biol Cryst Commun,
65,
327-330.
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PDB code:
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M.K.Hayashi,
C.Tang,
C.Verpelli,
R.Narayanan,
M.H.Stearns,
R.M.Xu,
H.Li,
C.Sala,
and
Y.Hayashi
(2009).
The postsynaptic density proteins Homer and Shank form a polymeric network structure.
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Cell,
137,
159-171.
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PDB codes:
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Y.Kong,
and
M.Karplus
(2009).
Signaling pathways of PDZ2 domain: a molecular dynamics interaction correlation analysis.
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Proteins,
74,
145-154.
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Z.N.Gerek,
O.Keskin,
and
S.B.Ozkan
(2009).
Identification of specificity and promiscuity of PDZ domain interactions through their dynamic behavior.
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Proteins,
77,
796-811.
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A.S.Fanning,
M.F.Lye,
J.M.Anderson,
and
A.Lavie
(2007).
Domain swapping within PDZ2 is responsible for dimerization of ZO proteins.
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J Biol Chem,
282,
37710-37716.
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PDB code:
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K.Handa,
T.Yugawa,
M.Narisawa-Saito,
S.Ohno,
M.Fujita,
and
T.Kiyono
(2007).
E6AP-dependent degradation of DLG4/PSD95 by high-risk human papillomavirus type 18 E6 protein.
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J Virol,
81,
1379-1389.
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M.Paduch,
M.Biernat,
P.Stefanowicz,
Z.S.Derewenda,
Z.Szewczuk,
and
J.Otlewski
(2007).
Bivalent peptides as models for multimeric targets of PDZ domains.
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Chembiochem,
8,
443-452.
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S.T.Runyon,
Y.Zhang,
B.A.Appleton,
S.L.Sazinsky,
P.Wu,
B.Pan,
C.Wiesmann,
N.J.Skelton,
and
S.S.Sidhu
(2007).
Structural and functional analysis of the PDZ domains of human HtrA1 and HtrA3.
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Protein Sci,
16,
2454-2471.
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PDB codes:
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T.Sugi,
T.Oyama,
T.Muto,
S.Nakanishi,
K.Morikawa,
and
H.Jingami
(2007).
Crystal structures of autoinhibitory PDZ domain of Tamalin: implications for metabotropic glutamate receptor trafficking regulation.
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EMBO J,
26,
2192-2205.
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PDB codes:
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Y.Zhang,
B.A.Appleton,
P.Wu,
C.Wiesmann,
and
S.S.Sidhu
(2007).
Structural and functional analysis of the ligand specificity of the HtrA2/Omi PDZ domain.
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Protein Sci,
16,
1738-1750.
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PDB code:
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Y.Zhang,
J.Dasgupta,
R.Z.Ma,
L.Banks,
M.Thomas,
and
X.S.Chen
(2007).
Structures of a human papillomavirus (HPV) E6 polypeptide bound to MAGUK proteins: mechanisms of targeting tumor suppressors by a high-risk HPV oncoprotein.
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J Virol,
81,
3618-3626.
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PDB codes:
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M.A.Stiffler,
V.P.Grantcharova,
M.Sevecka,
and
G.MacBeath
(2006).
Uncovering quantitative protein interaction networks for mouse PDZ domains using protein microarrays.
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J Am Chem Soc,
128,
5913-5922.
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N.Basdevant,
H.Weinstein,
and
M.Ceruso
(2006).
Thermodynamic basis for promiscuity and selectivity in protein-protein interactions: PDZ domains, a case study.
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J Am Chem Soc,
128,
12766-12777.
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R.H.Kedlaya,
K.M.Bhat,
J.Mitchell,
S.J.Darnell,
and
V.Setaluri
(2006).
TRP1 interacting PDZ-domain protein GIPC forms oligomers and is localized to intracellular vesicles in human melanocytes.
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Arch Biochem Biophys,
454,
160-169.
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A.E.Duquesne,
M.Ruijter,
J.Brouwer,
J.W.Drijfhout,
S.B.Nabuurs,
C.A.Spronk,
G.W.Vuister,
M.Ubbink,
and
G.W.Canters
(2005).
Solution structure of the second PDZ domain of the neuronal adaptor X11alpha and its interaction with the C-terminal peptide of the human copper chaperone for superoxide dismutase.
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J Biomol NMR,
32,
209-218.
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PDB code:
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E.Kalay,
A.P.de Brouwer,
R.Caylan,
S.B.Nabuurs,
B.Wollnik,
A.Karaguzel,
J.G.Heister,
H.Erdol,
F.P.Cremers,
C.W.Cremers,
H.G.Brunner,
and
H.Kremer
(2005).
A novel D458V mutation in the SANS PDZ binding motif causes atypical Usher syndrome.
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J Mol Med,
83,
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T.Cierpicki,
J.H.Bushweller,
and
Z.S.Derewenda
(2005).
Probing the supramodular architecture of a multidomain protein: the structure of syntenin in solution.
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Structure,
13,
319-327.
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C.L.Kielkopf,
S.Lücke,
and
M.R.Green
(2004).
U2AF homology motifs: protein recognition in the RRM world.
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Genes Dev,
18,
1513-1526.
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L.C.van den Berk,
M.A.van Ham,
M.M.te Lindert,
T.Walma,
J.Aelen,
G.W.Vuister,
and
W.J.Hendriks
(2004).
The interaction of PTP-BL PDZ domains with RIL: an enigmatic role for the RIL LIM domain.
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Mol Biol Rep,
31,
203-215.
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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
