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PDBsum entry 1n7f
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Protein binding
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PDB id
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1n7f
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Contents |
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* Residue conservation analysis
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PDB id:
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Protein binding
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Title:
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Crystal structure of the sixth pdz domain of grip1 in complex with liprin c-terminal peptide
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Structure:
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Ampa receptor interacting protein grip. Chain: a, b. Fragment: sixth pdz domain. Synonym: glutamate receptor interacting protein 1. Engineered: yes. 8-mer peptide from interacting protein (liprin). Chain: c, d. Engineered: yes
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Source:
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Rattus norvegicus. Norway rat. Organism_taxid: 10116. Gene: grip1. Expressed in: escherichia coli bl21(de3). Expression_system_taxid: 469008. Synthetic: yes. Other_details: the sequence of this chemically synthetized octa peptide occurs in thE C-termiuns of human liprin alpha protein
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Biol. unit:
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Tetramer (from
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Resolution:
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1.80Å
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R-factor:
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0.200
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R-free:
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0.222
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Authors:
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Y.J.Im,S.H.Park,S.H.Rho,J.H.Lee,G.B.Kang,M.Sheng,E.Kim,S.H.Eom
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Key ref:
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Y.J.Im
et al.
(2003).
Crystal structure of GRIP1 PDZ6-peptide complex reveals the structural basis for class II PDZ target recognition and PDZ domain-mediated multimerization.
J Biol Chem,
278,
8501-8507.
PubMed id:
DOI:
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Date:
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14-Nov-02
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Release date:
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12-Aug-03
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PROCHECK
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Headers
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References
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P97879
(GRIP1_RAT) -
Glutamate receptor-interacting protein 1 from Rattus norvegicus
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Seq:
Struc:
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1112 a.a.
86 a.a.
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Key: |
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PfamA domain |
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Secondary structure |
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CATH domain |
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DOI no:
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J Biol Chem
278:8501-8507
(2003)
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PubMed id:
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Crystal structure of GRIP1 PDZ6-peptide complex reveals the structural basis for class II PDZ target recognition and PDZ domain-mediated multimerization.
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Y.J.Im,
S.H.Park,
S.H.Rho,
J.H.Lee,
G.B.Kang,
M.Sheng,
E.Kim,
S.H.Eom.
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ABSTRACT
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PDZ domains bind to short segments within target proteins in a sequence-specific
fashion. Glutamate receptor-interacting protein (GRIP)/ABP family proteins
contain six to seven PDZ domains and interact via the sixth PDZ domain (class
II) with the C termini of various proteins including liprin-alpha. In addition
the PDZ456 domain mediates the formation of homo- and heteromultimers of GRIP
proteins. To better understand the structural basis of peptide recognition by a
class II PDZ domain and PDZ-mediated multimerization, we determined the crystal
structures of the GRIP1 PDZ6 domain alone and in complex with a synthetic
C-terminal octapeptide of human liprin-alpha at resolutions of 1.5 and 1.8 A,
respectively. Remarkably, unlike other class II PDZ domains, Ile-736 at alphaB5
rather than conserved Leu-732 at alphaB1 makes a direct hydrophobic contact with
the side chain of the Tyr at the -2 position of the ligand. Moreover, the
peptide-bound structure of PDZ6 shows a slight reorientation of helix alphaB,
indicating that the second hydrophobic pocket undergoes a conformational
adaptation to accommodate the bulkiness of the Tyr side chain, and forms an
antiparallel dimer through an interface located at a site distal to the
peptide-binding groove. This configuration may enable formation of GRIP
multimers and efficient clustering of GRIP-binding proteins.
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Selected figure(s)
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Figure 3.
Fig. 3. The peptide-binding site. A, ball and stick model
of the peptide binding pocket and its specific ligand
(ATVRTYSC). Only the last four residues of the peptide are shown
(green), and for clarity only side chains of the residues
involved in the peptide binding are shown. Dashed lines
represent hydrogen bonds around the carboxylate binding site. A
water molecule, shown as a red ball, forms a hydrogen bond with
one of the ligand C-terminal carboxylic oxygen atoms. The
majority of the hydrogen bonds are between the peptide backbone
and the carboxylate-binding loop or strand  B. B,
molecular surfaces of GRIP PDZ6 showing the hydrophobic binding
pocket and the bound peptide. The hydrophobic residues are
colored white, and the hydrophobic side chains within the
binding pocket are colored in gray scale. The polar, acidic, and
basic residues are colored yellow, red, and blue respectively.
The two hydrophobic binding pockets are indicated by circles.
The side chains of hydrophobic ligand residues Cys-0 and Try-1
dip into the hydrophobic binding pockets. C, conformational
changes upon peptide binding. Superposition of the peptide-free
and peptide-bound structures was done using the six -strands,
which do not undergo conformational change upon peptide binding.
The peptide-free and peptide-bound PDZ structures are shown in
white and gray, respectively. The segments that undergo large
conformational changes upon peptide binding are colored black.
D, ball and stick model showing a conformational change of
Ile-736. Peptide-bound PDZ6 is colored dark blue;
self-associated PDZ6 is colored green. The peptide ligand and
C-terminal tail of the PDZ6 construct are colored pale blue and
yellow, respectively. The bulky hydrophobic side chain of Tyr-2
makes hydrophobic contact with Ile-736.
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Figure 4.
Fig. 4. Dimerization of GRIP PDZ6. A, dimeric structure
of PDZ6 domain. PDZ6 domains form a dimer via interaction of
antiparallel A strands
and  A- D loops.
Peptide ligands bound to the opposite side of the PDZ6 dimer are
represented in ball-and-stick. B, self-association of two GRIP
PDZ6 domains related by a 2-fold crystallographic axis was
observed in the peptide-free PDZ6 crystal. Each C terminus
serves as a ligand for a neighboring PDZ molecule. C, effects of
mutations on dimerization. Molecular weights of mutants Y671D
and R731D and a wild type PDZ domain were estimated by size
exclusion chromatography (Superdex 75 HR 16/60 column). The
mutated residues, Y671D and R718D, were shown in ball and stick
with van der Waals radius in A and B. The elution profiles of a
wild type, Y671D and R718D mutants. This result suggests that
the dimer in solution is the form shown in A. D, the variable
residues within the PDZ6 domains of GRIP homologues are
represented in ball-and-stick. Only one variable residue,
Ile-669, which is Val in GRIP2, is located in the dimeric
interface.
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The above figures are
reprinted
by permission from the ASBMB:
J Biol Chem
(2003,
278,
8501-8507)
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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K.Kaufmann,
N.Shen,
L.Mizoue,
and
J.Meiler
(2011).
A physical model for PDZ-domain/peptide interactions.
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J Mol Model,
17,
315-324.
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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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S.Kalyoncu,
O.Keskin,
and
A.Gursoy
(2010).
Interaction prediction and classification of PDZ domains.
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BMC Bioinformatics,
11,
357.
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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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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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J.L.Sanford,
T.A.Mays,
K.D.Varian,
J.B.Wilson,
P.M.Janssen,
and
J.A.Rafael-Fortney
(2008).
Truncated CASK does not alter skeletal muscle or protein interactors.
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Muscle Nerve,
38,
1116-1127.
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T.Ochiishi,
K.Futai,
K.Okamoto,
K.Kameyama,
and
K.S.Kosik
(2008).
Regulation of AMPA receptor trafficking by delta-catenin.
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Mol Cell Neurosci,
39,
499-507.
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W.Yu,
E.I.Charych,
D.R.Serwanski,
R.W.Li,
R.Ali,
B.A.Bahr,
and
A.L.De Blas
(2008).
Gephyrin interacts with the glutamate receptor interacting protein 1 isoforms at GABAergic synapses.
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J Neurochem,
105,
2300-2314.
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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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F.Baumgart,
J.M.Mancheño,
and
I.Rodríguez-Crespo
(2007).
Insights into the activation of brain serine racemase by the multi-PDZ domain glutamate receptor interacting protein, divalent cations and ATP.
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FEBS J,
274,
4561-4571.
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F.C.Morales,
Y.Takahashi,
S.Momin,
H.Adams,
X.Chen,
and
M.M.Georgescu
(2007).
NHERF1/EBP50 head-to-tail intramolecular interaction masks association with PDZ domain ligands.
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Mol Cell Biol,
27,
2527-2537.
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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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Q.Chen,
X.Niu,
Y.Xu,
J.Wu,
and
Y.Shi
(2007).
Solution structure and backbone dynamics of the AF-6 PDZ domain/Bcr peptide complex.
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Protein Sci,
16,
1053-1062.
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PDB code:
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R.Enz
(2007).
The trick of the tail: protein-protein interactions of metabotropic glutamate receptors.
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Bioessays,
29,
60-73.
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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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E.I.Charych,
R.Li,
D.R.Serwanski,
X.Li,
C.P.Miralles,
N.Pinal,
and
A.L.De Blas
(2006).
Identification and characterization of two novel splice forms of GRIP1 in the rat brain.
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J Neurochem,
97,
884-898.
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H.Kusunoki,
and
T.Kohno
(2006).
Solution structure of human erythroid p55 PDZ domain.
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Proteins,
64,
804-807.
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PDB code:
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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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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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E.Kim,
and
M.Sheng
(2004).
PDZ domain proteins of synapses.
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Nat Rev Neurosci,
5,
771-781.
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B.S.Kang,
D.R.Cooper,
Y.Devedjiev,
U.Derewenda,
and
Z.S.Derewenda
(2003).
Molecular roots of degenerate specificity in syntenin's PDZ2 domain: reassessment of the PDZ recognition paradigm.
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Structure,
11,
845-853.
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PDB codes:
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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
