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PDBsum entry 1y9c
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Signaling protein
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PDB id
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1y9c
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Theoretical model |
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PDB id:
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Signaling protein
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Title:
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Homology model of the human p2y12 receptor
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Structure:
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P2y purinoceptor 12. Chain: a. Synonym: p2y12, p2y12 platelet adp receptor, p2yadp, adp- glucose receptor, adpg-r, p2yac, p2ycyc, p2tac, sp1999
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Source:
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Homo sapiens. Human
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Authors:
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S.Costanzi
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Key ref:
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S.Costanzi
et al.
(2004).
Architecture of P2Y nucleotide receptors: structural comparison based on sequence analysis, mutagenesis, and homology modeling.
J Med Chem,
47,
5393-5404.
PubMed id:
DOI:
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Date:
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15-Dec-04
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Release date:
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18-Jan-05
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PROCHECK
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Headers
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References
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Q9H244
(P2Y12_HUMAN) -
P2Y purinoceptor 12
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Seq:
Struc:
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342 a.a.
302 a.a.
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Key: |
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PfamA domain |
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Secondary structure |
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DOI no:
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J Med Chem
47:5393-5404
(2004)
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PubMed id:
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Architecture of P2Y nucleotide receptors: structural comparison based on sequence analysis, mutagenesis, and homology modeling.
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S.Costanzi,
L.Mamedova,
Z.G.Gao,
K.A.Jacobson.
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ABSTRACT
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Human P2Y receptors encompass at least eight subtypes of Class A G
protein-coupled receptors (GPCRs), responding to adenine and/or uracil
nucleotides. Using a BLAST search against the Homo sapiens subset of the
SWISS-PROT and TrEMBL databases, we identified 68 proteins showing high
similarity to P2Y receptors. To address the problem of low sequence identity
between rhodopsin and the P2Y receptors, we performed a multiple-sequence
alignment of the retrieved proteins and the template bovine rhodopsin, combining
manual identification of the transmembrane domains (TMs) with automatic
techniques. The resulting phylogenetic tree delineated two distinct subgroups of
P2Y receptors: Gq-coupled subtypes (e.g., P2Y1) and those coupled to Gi (e.g.,
P2Y12). On the basis of sequence comparison we mutated three Tyr residues of the
putative P2Y1 binding pocket to Ala and Phe and characterized pharmacologically
the mutant receptors expressed in COS-7 cells. The mutation of Y306 (7.35, site
of a cationic residue in P2Y12) or Y203 in the second extracellular loop
selectively decreased the affinity of the agonist 2-MeSADP, and the Y306F
mutation also reduced antagonist (MRS2179) affinity by 5-fold. The Y273A (6.48)
mutation precluded the receptor activation without a major effect on the
ligand-binding affinities, but the Y273F mutant receptor still activated G
proteins with full agonist affinity. Thus, we have identified new recognition
elements to further define the P2Y1 binding site and related these to other P2Y
receptor subtypes. Following sequence-based secondary-structure prediction, we
constructed complete models of all the human P2Y receptors by homology to
rhodopsin. Ligand docking on P2Y1 and P2Y12 receptor models was guided by
mutagenesis results, to identify the residues implicated in the binding process.
Different sets of cationic residues in the two subgroups appeared to coordinate
phosphate-bearing ligands. Within the P2Y1 subgroup these residues are R3.29,
K/R6.55, and R7.39. Within the P2Y12 subgroup, the only residue in common with
P2Y1 is R6.55, and the role of R3.29 in TM3 seems to be fulfilled by a Lys
residue in EL2, whereas the R7.39 in TM7 seems to be substituted by K7.35. Thus,
we have identified common and distinguishing features of P2Y receptor structure
and have proposed modes of ligand binding for the two representative subtypes
that already have well-developed ligands.
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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.D.Qi,
D.Houston-Cohen,
I.Naruszewicz,
T.K.Harden,
and
R.A.Nicholas
(2011).
Ser352 and Ser354 in the carboxyl terminus of the human P2Y(1) receptor are required for agonist-promoted phosphorylation and internalization in MDCK cells.
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Br J Pharmacol,
162,
1304-1313.
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F.Deflorian,
and
K.A.Jacobson
(2011).
Comparison of three GPCR structural templates for modeling of the P2Y(12) nucleotide receptor.
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J Comput Aided Mol Des,
25,
329-338.
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H.Liu,
H.Ge,
Y.Peng,
P.Xiao,
and
J.Xu
(2011).
Molecular mechanism of action for reversible P2Y12 antagonists.
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Biophys Chem,
155,
74-81.
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S.Bhatnagar,
S.Mishra,
and
R.Pathak
(2011).
Mining human genome for novel purinergic P2Y receptors: a sequence analysis and molecular modeling approach.
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J Recept Signal Transduct Res,
31,
75-84.
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A.Norambuena,
F.Palma,
M.I.Poblete,
M.V.Donoso,
E.Pardo,
A.González,
and
J.P.Huidobro-Toro
(2010).
UTP controls cell surface distribution and vasomotor activity of the human P2Y2 receptor through an epidermal growth factor receptor-transregulated mechanism.
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J Biol Chem,
285,
2940-2950.
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C.Parravicini,
M.P.Abbracchio,
P.Fantucci,
and
G.Ranghino
(2010).
Forced unbinding of GPR17 ligands from wild type and R255I mutant receptor models through a computational approach.
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BMC Struct Biol,
10,
8.
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C.S.Sum,
I.G.Tikhonova,
S.Costanzi,
and
M.C.Gershengorn
(2009).
Two Arginine-Glutamate Ionic Locks Near the Extracellular Surface of FFAR1 Gate Receptor Activation.
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J Biol Chem,
284,
3529-3536.
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K.A.Jacobson,
A.A.Ivanov,
S.de Castro,
T.K.Harden,
and
H.Ko
(2009).
Development of selective agonists and antagonists of P2Y receptors.
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Purinergic Signal,
5,
75-89.
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M.E.Daly,
B.B.Dawood,
W.A.Lester,
I.R.Peake,
F.Rodeghiero,
A.C.Goodeve,
M.Makris,
J.T.Wilde,
A.D.Mumford,
S.P.Watson,
and
S.J.Mundell
(2009).
Identification and characterization of a novel P2Y 12 variant in a patient diagnosed with type 1 von Willebrand disease in the European MCMDM-1VWD study.
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Blood,
113,
4110-4113.
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S.Costanzi,
J.Siegel,
I.G.Tikhonova,
and
K.A.Jacobson
(2009).
Rhodopsin and the others: a historical perspective on structural studies of G protein-coupled receptors.
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Curr Pharm Des,
15,
3994-4002.
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S.N.Fatakia,
S.Costanzi,
and
C.C.Chow
(2009).
Computing highly correlated positions using mutual information and graph theory for G protein-coupled receptors.
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PLoS ONE,
4,
e4681.
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A.M.Silva,
R.J.Rodrigues,
A.R.Tomé,
R.A.Cunha,
S.Misler,
L.M.Rosário,
and
R.M.Santos
(2008).
Electrophysiological and immunocytochemical evidence for P2X purinergic receptors in pancreatic beta cells.
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Pancreas,
36,
279-283.
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C.Parravicini,
G.Ranghino,
M.P.Abbracchio,
and
P.Fantucci
(2008).
GPR17: molecular modeling and dynamics studies of the 3-D structure and purinergic ligand binding features in comparison with P2Y receptors.
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BMC Bioinformatics,
9,
263.
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D.Ecke,
B.Fischer,
and
G.Reiser
(2008).
Diastereoselectivity of the P2Y11 nucleotide receptor: mutational analysis.
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Br J Pharmacol,
155,
1250-1255.
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S.Costanzi,
S.Neumann,
and
M.C.Gershengorn
(2008).
Seven transmembrane-spanning receptors for free fatty acids as therapeutic targets for diabetes mellitus: pharmacological, phylogenetic, and drug discovery aspects.
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J Biol Chem,
283,
16269-16273.
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S.Costanzi
(2008).
On the applicability of GPCR homology models to computer-aided drug discovery: a comparison between in silico and crystal structures of the beta2-adrenergic receptor.
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J Med Chem,
51,
2907-2914.
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A.A.Ivanov,
I.Fricks,
T.Kendall Harden,
and
K.A.Jacobson
(2007).
Molecular dynamics simulation of the P2Y14 receptor. Ligand docking and identification of a putative binding site of the distal hexose moiety.
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Bioorg Med Chem Lett,
17,
761-766.
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A.R.Tomé,
E.Castro,
R.M.Santos,
and
L.M.Rosário
(2007).
Functional distribution of Ca2+-coupled P2 purinergic receptors among adrenergic and noradrenergic bovine adrenal chromaffin cells.
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BMC Neurosci,
8,
39.
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G.Kleinau,
M.Claus,
H.Jaeschke,
S.Mueller,
S.Neumann,
R.Paschke,
and
G.Krause
(2007).
Contacts between extracellular loop two and transmembrane helix six determine basal activity of the thyroid-stimulating hormone receptor.
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J Biol Chem,
282,
518-525.
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T.Schöneberg,
T.Hermsdorf,
E.Engemaier,
K.Engel,
I.Liebscher,
D.Thor,
K.Zierau,
H.Römpler,
and
A.Schulz
(2007).
Structural and functional evolution of the P2Y(12)-like receptor group.
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Purinergic Signal,
3,
255-268.
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A.A.Ivanov,
S.Costanzi,
and
K.A.Jacobson
(2006).
Defining the nucleotide binding sites of P2Y receptors using rhodopsin-based homology modeling.
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J Comput Aided Mol Des,
20,
417-426.
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C.Volonté,
S.Amadio,
N.D'Ambrosi,
M.Colpi,
and
G.Burnstock
(2006).
P2 receptor web: complexity and fine-tuning.
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Pharmacol Ther,
112,
264-280.
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D.Ecke,
M.E.Tulapurkar,
V.Nahum,
B.Fischer,
and
G.Reiser
(2006).
Opposite diastereoselective activation of P2Y1 and P2Y11 nucleotide receptors by adenosine 5'-O-(alpha-boranotriphosphate) analogues.
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Br J Pharmacol,
149,
416-423.
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I.von Kügelgen
(2006).
Pharmacological profiles of cloned mammalian P2Y-receptor subtypes.
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Pharmacol Ther,
110,
415-432.
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J.S.Surgand,
J.Rodrigo,
E.Kellenberger,
and
D.Rognan
(2006).
A chemogenomic analysis of the transmembrane binding cavity of human G-protein-coupled receptors.
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Proteins,
62,
509-538.
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S.Moore,
H.Jaeschke,
G.Kleinau,
S.Neumann,
S.Costanzi,
J.K.Jiang,
J.Childress,
B.M.Raaka,
A.Colson,
R.Paschke,
G.Krause,
C.J.Thomas,
and
M.C.Gershengorn
(2006).
Evaluation of small-molecule modulators of the luteinizing hormone/choriogonadotropin and thyroid stimulating hormone receptors: structure-activity relationships and selective binding patterns.
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J Med Chem,
49,
3888-3896.
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Y.Zhang,
M.E.Devries,
and
J.Skolnick
(2006).
Structure modeling of all identified G protein-coupled receptors in the human genome.
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PLoS Comput Biol,
2,
e13.
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P.Besada,
L.Mamedova,
C.J.Thomas,
S.Costanzi,
and
K.A.Jacobson
(2005).
Design and synthesis of new bicyclic diketopiperazines as scaffolds for receptor probes of structurally diverse functionality.
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Org Biomol Chem,
3,
2016-2025.
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S.Costanzi,
B.V.Joshi,
S.Maddileti,
L.Mamedova,
M.J.Gonzalez-Moa,
V.E.Marquez,
T.K.Harden,
and
K.A.Jacobson
(2005).
Human P2Y(6) receptor: molecular modeling leads to the rational design of a novel agonist based on a unique conformational preference.
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J Med Chem,
48,
8108-8111.
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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.
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