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PDBsum entry 1b0h
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Peptide binding protein
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PDB id
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1b0h
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Contents |
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* Residue conservation analysis
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DOI no:
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Protein Sci
8:1432-1444
(1999)
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PubMed id:
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Relating structure to thermodynamics: the crystal structures and binding affinity of eight OppA-peptide complexes.
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T.G.Davies,
R.E.Hubbard,
J.R.Tame.
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ABSTRACT
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The oligopeptide-binding protein OppA provides a useful model system for
studying the physical chemistry underlying noncovalent interactions since it
binds a variety of readily synthesized ligands. We have studied the binding of
eight closely related tripeptides of the type Lysine-X-Lysine, where X is an
abnormal amino acid, by isothermal titration calorimetry (ITC) and X-ray
crystallography. The tripeptides fall into three series of ligands, which have
been designed to examine the effects of small changes to the central side chain.
Three ligands have a primary amine as the second side chain, two have a straight
alkane chain, and three have ring systems. The results have revealed a definite
preference for the binding of hydrophobic residues over the positively charged
side chains, the latter binding only weakly due to unfavorable enthalpic
effects. Within the series of positively charged groups, a point of lowest
affinity has been identified and this is proposed to arise from unfavorable
electrostatic interactions in the pocket, including the disruption of a key salt
bridge. Marked entropy-enthalpy compensation is found across the series, and
some of the difficulties in designing tightly binding ligands have been
highlighted.
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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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F.Tian,
L.Yang,
F.Lv,
X.Luo,
and
Y.Pan
(2011).
Why OppA protein can bind sequence-independent peptides? A combination of QM/MM, PB/SA, and structure-based QSAR analyses.
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Amino Acids,
40,
493-503.
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S.Y.Lu,
Y.J.Jiang,
J.Lv,
J.W.Zou,
and
T.X.Wu
(2011).
Role of bridging water molecules in GSK3β-inhibitor complexes: insights from QM/MM, MD, and molecular docking studies.
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J Comput Chem,
32,
1907-1918.
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C.Bissantz,
B.Kuhn,
and
M.Stahl
(2010).
A medicinal chemist's guide to molecular interactions.
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J Med Chem,
53,
5061-5084.
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A.Taneoka,
A.Sakaguchi-Mikami,
T.Yamazaki,
W.Tsugawa,
and
K.Sode
(2009).
The construction of a glucose-sensing luciferase.
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Biosens Bioelectron,
25,
76-81.
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A.Sakaguchi-Mikami,
A.Taneoka,
R.Yamoto,
S.Ferri,
and
K.Sode
(2008).
Engineering of ligand specificity of periplasmic binding protein for glucose sensing.
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Biotechnol Lett,
30,
1453-1460.
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A.Sakaguchi,
S.Ferri,
W.Tsugawa,
and
K.Sode
(2007).
Novel fluorescent sensing system for alpha-fructosyl amino acids based on engineered fructosyl amino acid binding protein.
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Biosens Bioelectron,
22,
1933-1938.
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D.B.Sherman,
S.Zhang,
J.B.Pitner,
and
A.Tropsha
(2004).
Evaluation of the relative stability of liganded versus ligand-free protein conformations using Simplicial Neighborhood Analysis of Protein Packing (SNAPP) method.
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Proteins,
56,
828-838.
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G.Kontopidis,
P.Taylor,
and
M.D.Walkinshaw
(2004).
Enzymatic and structural characterization of non-peptide ligand-cyclophilin complexes.
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Acta Crystallogr D Biol Crystallogr,
60,
479-485.
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PDB codes:
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A.M.Hays,
H.B.Gray,
and
D.B.Goodin
(2003).
Trapping of peptide-based surrogates in an artificially created channel of cytochrome c peroxidase.
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Protein Sci,
12,
278-287.
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K.Benkestock,
P.O.Edlund,
and
J.Roeraade
(2002).
On-line microdialysis for enhanced resolution and sensitivity during electrospray mass spectrometry of non-covalent complexes and competitive binding studies.
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Rapid Commun Mass Spectrom,
16,
2054-2059.
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F.C.Lanfermeijer,
F.J.Detmers,
W.N.Konings,
and
B.Poolman
(2000).
On the binding mechanism of the peptide receptor of the oligopeptide transport system of Lactococcus lactis.
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EMBO J,
19,
3649-3656.
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F.J.Detmers,
F.C.Lanfermeijer,
R.Abele,
R.W.Jack,
R.Tampe,
W.N.Konings,
and
B.Poolman
(2000).
Combinatorial peptide libraries reveal the ligand-binding mechanism of the oligopeptide receptor OppA of Lactococcus lactis.
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Proc Natl Acad Sci U S A,
97,
12487-12492.
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H.J.Böhm,
and
M.Stahl
(2000).
Structure-based library design: molecular modelling merges with combinatorial chemistry.
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Curr Opin Chem Biol,
4,
283-286.
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J.Habash,
J.Raftery,
R.Nuttall,
H.J.Price,
C.Wilkinson,
A.J.Kalb,
and
J.R.Helliwell
(2000).
Direct determination of the positions of the deuterium atoms of the bound water in -concanavalin A by neutron Laue crystallography.
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Acta Crystallogr D Biol Crystallogr,
56,
541-550.
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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
