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PDBsum entry 2rox
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* Residue conservation analysis
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DOI no:
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Acta Crystallogr D Biol Crystallogr
52:758-765
(1996)
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PubMed id:
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Structures of human transthyretin complexed with thyroxine at 2.0 A resolution and 3',5'-dinitro-N-acetyl-L-thyronine at 2.2 A resolution.
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A.Wojtczak,
V.Cody,
J.R.Luft,
W.Pangborn.
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ABSTRACT
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The molecular structures of two human transthyretin (hTTR, prealbumin)
complexes, co-crystallized with thyroxine (3,5,3',5'-tetraiodo-L-thyronine;
T(4)), and with 3',5'-dinitro-N-acetyl-LL-thyronine (DNNAT), were determined by
X-ray diffraction methods. Crystals of both structures are orthorhombic, space
group P2(1)2(1)2, and have two independent monomers in the asymmetric unit of
the crystal lattice. These structures have been refined to 17.0% for 8-2.0 A
resolution data for the T(4) complex (I), and to R = 18.4% for 8-2.2 A
resolution data for the DNNAT structure (II). This report provides a detailed
description of T(4) binding to wild-type hTTR at 2.0 A resolution, as well as
DNNAT. In both structures, the two independent hormone-binding sites of the TTR
tetramer are occupied by ligand. A 50% statistical disorder model was applied to
account for the crystallographic twofold symmetry along the binding channel and
the lack of such symmetry for the ligands. Results for the co-crystallized T(4)
complex show that T(4) binds deep in the hormone-binding channel and displaces
the bound water previously reported for T(4) soaked into a native transthyretin
crystal [Blake & Oatley (1977). Nature (London), 268, 115-120]. DNNAT also
binds deeper in the channel toward the tetramer center than T(4) with the nitro
groups occupying the symmetrical innermost halogen pockets. The N-acetyl moiety
does not form polar contacts with the protein side chains as it is oriented
toward the center of the channel. The weak binding affinity of DNNAT results
from the loss of hydrophobic interactions with the halogen binding pockets as
observed in T(4) binding. These data suggest that the halogen-binding sites
toward the tetramer center are of primary importance as they are occupied by
analogues with weak affinity to TTR, and are therefore selected over the other
halogen sites which contribute more strongly to the overall binding affinity.
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Selected figure(s)
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Figure 1.
Fig. 1. The a-carbon representation of the human transthyretin
quaternary structure showing the two independent monomeric
subunits A and B forming the twofold-related tetramer with
monomers labeled A' and B'. The tetramer is projected down the a
axis. The van der Waals surface of thyroxine is shown in the
TTR-binding sites.
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Figure 3.
Fig. 3. Omit
(F
o -F,)
electron-density map, contoured at 5or, for
hTTR-T 4 indicating the iodine positions of thyroxine in binding
domain A. This model shows that the hormone binds with its
phenolic ring near the tetramer center.
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The above figures are
reprinted
by permission from the IUCr:
Acta Crystallogr D Biol Crystallogr
(1996,
52,
758-765)
copyright 1996.
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Figures were
selected
by the author.
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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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S.Choi,
N.Reixach,
S.Connelly,
S.M.Johnson,
I.A.Wilson,
and
J.W.Kelly
(2010).
A substructure combination strategy to create potent and selective transthyretin kinetic stabilizers that prevent amyloidogenesis and cytotoxicity.
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J Am Chem Soc,
132,
1359-1370.
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PDB codes:
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S.Connelly,
S.Choi,
S.M.Johnson,
J.W.Kelly,
and
I.A.Wilson
(2010).
Structure-based design of kinetic stabilizers that ameliorate the transthyretin amyloidoses.
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Curr Opin Struct Biol,
20,
54-62.
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S.E.Kolstoe,
P.P.Mangione,
V.Bellotti,
G.W.Taylor,
G.A.Tennent,
S.Deroo,
A.J.Morrison,
A.J.Cobb,
A.Coyne,
M.G.McCammon,
T.D.Warner,
J.Mitchell,
R.Gill,
M.D.Smith,
S.V.Ley,
C.V.Robinson,
S.P.Wood,
and
M.B.Pepys
(2010).
Trapping of palindromic ligands within native transthyretin prevents amyloid formation.
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Proc Natl Acad Sci U S A,
107,
20483-20488.
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PDB codes:
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P.Prapunpoj,
and
L.Leelawatwattana
(2009).
Evolutionary changes to transthyretin: structure-function relationships.
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FEBS J,
276,
5330-5341.
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S.J.Hyung,
C.V.Robinson,
and
B.T.Ruotolo
(2009).
Gas-phase unfolding and disassembly reveals stability differences in ligand-bound multiprotein complexes.
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Chem Biol,
16,
382-390.
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S.K.Palaninathan,
N.N.Mohamedmohaideen,
E.Orlandini,
G.Ortore,
S.Nencetti,
A.Lapucci,
A.Rossello,
J.S.Freundlich,
and
J.C.Sacchettini
(2009).
Novel transthyretin amyloid fibril formation inhibitors: synthesis, biological evaluation, and X-ray structural analysis.
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PLoS One,
4,
e6290.
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PDB codes:
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J.Sørensen,
D.Hamelberg,
B.Schiøtt,
and
J.A.McCammon
(2007).
Comparative MD analysis of the stability of transthyretin providing insight into the fibrillation mechanism.
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Biopolymers,
86,
73-82.
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R.L.Julius,
O.K.Farha,
J.Chiang,
L.J.Perry,
and
M.F.Hawthorne
(2007).
Synthesis and evaluation of transthyretin amyloidosis inhibitors containing carborane pharmacophores.
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Proc Natl Acad Sci U S A,
104,
4808-4813.
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P.Prapunpoj,
L.Leelawatwatana,
G.Schreiber,
and
S.J.Richardson
(2006).
Change in structure of the N-terminal region of transthyretin produces change in affinity of transthyretin to T4 and T3.
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FEBS J,
273,
4013-4023.
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R.H.Lilien,
B.W.Stevens,
A.C.Anderson,
and
B.R.Donald
(2005).
A novel ensemble-based scoring and search algorithm for protein redesign and its application to modify the substrate specificity of the gramicidin synthetase a phenylalanine adenylation enzyme.
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J Comput Biol,
12,
740-761.
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A.Busse,
M.A.Sánchez,
V.Monterroso,
M.V.Alvarado,
and
P.León
(2004).
A severe form of amyloidotic polyneuropathy in a Costa Rican family with a rare transthyretin mutation (Glu54Lys).
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Am J Med Genet A,
128,
190-194.
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A.Katrusiak,
and
A.Katrusiak
(2004).
Thyroxine revisited.
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J Pharm Sci,
93,
3066-3075.
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R.E.Steward,
M.W.MacArthur,
R.A.Laskowski,
and
J.M.Thornton
(2003).
Molecular basis of inherited diseases: a structural perspective.
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Trends Genet,
19,
505-513.
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T.Eneqvist,
E.Lundberg,
L.Nilsson,
R.Abagyan,
and
A.E.Sauer-Eriksson
(2003).
The transthyretin-related protein family.
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Eur J Biochem,
270,
518-532.
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J.A.Wilce,
N.L.Daly,
and
D.J.Craik
(2002).
Synthesis and structural analysis of the N-terminal domain of the thyroid hormone-binding protein transthyretin.
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Clin Chem Lab Med,
40,
1221-1228.
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V.Cody
(2002).
Mechanisms of molecular recognition: crystal structure analysis of human and rat transthyretin inhibitor complexes.
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Clin Chem Lab Med,
40,
1237-1243.
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J.T.White,
and
J.W.Kelly
(2001).
Support for the multigenic hypothesis of amyloidosis: the binding stoichiometry of retinol-binding protein, vitamin A, and thyroid hormone influences transthyretin amyloidogenicity in vitro.
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Proc Natl Acad Sci U S A,
98,
13019-13024.
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A.R.Aldred,
P.Prapunpoj,
and
G.Schreiber
(1997).
Evolution of shorter and more hydrophilic transthyretin N-termini by stepwise conversion of exon 2 into intron 1 sequences (shifting the 3' splice site of intron 1)
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Eur J Biochem,
246,
401-409.
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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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