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PDBsum entry 1vqj
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DNA binding protein
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PDB id
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1vqj
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Contents |
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* Residue conservation analysis
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DOI no:
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J Mol Biol
259:148-159
(1996)
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PubMed id:
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Context dependence of mutational effects in a protein: the crystal structures of the V35I, I47V and V35I/I47V gene V protein core mutants.
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H.Zhang,
M.M.Skinner,
W.S.Sandberg,
A.H.Wang,
T.C.Terwilliger.
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ABSTRACT
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The basis for the context dependence of the effects of core mutations on protein
stability was investigated by comparing the structures of three gene V protein
mutants with that of the wild-type protein. We previously examined a "swapped"
mutant in which core residues Val35 and Ile47 were simply reversed so that the
mutant had no hydrophobicity change from the native protein. The swapped mutant
was destabilized by 3 kcal/mol per gene V protein dimer relative to the
wild-type protein, demonstrating that factors other than hydrophobicity must
make substantial contributions to the effects of mutations on the stability of
the protein. Here we have determined the structure of this swapped mutant
(V35I/I47V) as well as those of the two constituent mutants (V35I and I47V). We
find that the structures of the mutant proteins are very similar to that of the
wild-type protein except for the necessary addition or deletion of methylene
groups and for slight positional shifts of atoms around each mutated residue.
The structure of the double mutant is a composite of the structures of the two
single mutants. In the mutant structures, the V35I mutation fills a cavity that
exists in the wild-type protein and the I47V mutation creates a new cavity. The
structures of the mutants indicate further that the reason the V35I and I47V
mutations do not have opposite effects on stability is that the cavity in the
wild-type protein filled by the V35I mutation is not optimally shaped for
accommodating the additional methylene group of the isoleucine. These results
support the concepts that the details of core packing have substantial influence
on the effects of core mutations on protein stability and that these packing
effects are major determinants of the context dependence of core mutation
effects on stability.
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Selected figure(s)
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Figure 2.
Figure 2. A stereo view of the difference Fourier maps at 1.8 Å showing the difference in electron density between
mutants and wild-type gene V protein. Amplitudes (Fmut - FWT ) were used, where Fmut and FWT are the observed
structure amplitudes for the mutant and wild-type structure. The phases were calculated from the refined gene V protein
model. The V35I and I47V maps are contoured at 3s and the V35I/I47V map at 2.5s for positive and negative contours,
where s is the root-mean-square density throughout the cell. Positive and negative electronic densities are displayed
in green and red, respectively. Yellow is red and green on top of each other. Coordinates are those for the wild-type
gene V protein. Nomenclature for atoms is as follows: CD1 and CD2 are equivalent to C
d1
and C
d2
, CG1 and CG2 are
equivalent to C
d1
and C
d2
, and CB is equivalent to C
b
. (a) V35I; (b) I47V; (c) V35I/I47V.
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Figure 4.
Figure 4. A close-up stereo view of the superposition of the structures of mutant gene V proteins (I47V, green; V35I,
magenta; V35I/I47V, cyan) on the structure of the wild-type protein (yellow lines). The mutant structures were first
aligned by least-squares superposition of the main-chain atoms on the wild-type. Only the relevant portions of the
structures are shown. The superposition of all mutants closely resemble that of the wild-type model as it is almost
impossible to distinguish color differences between the models except at the mutated site. Also, the two single mutants
in (a) closely resemble those of the double mutant in (b). For atom nomenclature see the legend to Figure 2. (a) V35I
and I47V versus WT; (b) V35I/I47V versus WT.
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The above figures are
reprinted
by permission from Elsevier:
J Mol Biol
(1996,
259,
148-159)
copyright 1996.
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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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W.Y.Lee,
C.R.Free,
and
S.M.Sine
(2009).
Binding to gating transduction in nicotinic receptors: Cys-loop energetically couples to pre-M1 and M2-M3 regions.
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J Neurosci,
29,
3189-3199.
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W.Y.Lee,
C.R.Free,
and
S.M.Sine
(2008).
Nicotinic receptor interloop proline anchors beta1-beta2 and Cys loops in coupling agonist binding to channel gating.
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J Gen Physiol,
132,
265-278.
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J.Font,
A.Benito,
J.Torrent,
R.Lange,
M.Ribó,
and
M.Vilanova
(2006).
Pressure- and temperature-induced unfolding studies: thermodynamics of core hydrophobicity and packing of ribonuclease A.
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Biol Chem,
387,
285-296.
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R.K.Jain,
and
R.Ranganathan
(2004).
Local complexity of amino acid interactions in a protein core.
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Proc Natl Acad Sci U S A,
101,
111-116.
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PDB codes:
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G.M.Süel,
S.W.Lockless,
M.A.Wall,
and
R.Ranganathan
(2003).
Evolutionarily conserved networks of residues mediate allosteric communication in proteins.
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Nat Struct Biol,
10,
59-69.
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C.Qu,
S.Akanuma,
N.Tanaka,
H.Moriyama,
and
T.Oshima
(2001).
Design, X-ray crystallography, molecular modelling and thermal stability studies of mutant enzymes at site 172 of 3-isopropylmalate dehydrogenase from Thermus thermophilus.
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Acta Crystallogr D Biol Crystallogr,
57,
225-232.
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PDB codes:
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T.Ohmura,
T.Ueda,
K.Ootsuka,
M.Saito,
and
T.Imoto
(2001).
Stabilization of hen egg white lysozyme by a cavity-filling mutation.
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Protein Sci,
10,
313-320.
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PDB codes:
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T.C.Mou,
C.W.Gray,
and
D.M.Gray
(1999).
The binding affinity of Ff gene 5 protein depends on the nearest-neighbor composition of the ssDNA substrate.
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Biophys J,
76,
1537-1551.
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G.A.Lazar,
and
T.M.Handel
(1998).
Hydrophobic core packing and protein design.
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Curr Opin Chem Biol,
2,
675-679.
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A.Akasako,
M.Haruki,
M.Oobatake,
and
S.Kanaya
(1997).
Conformational stabilities of Escherichia coli RNase HI variants with a series of amino acid substitutions at a cavity within the hydrophobic core.
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J Biol Chem,
272,
18686-18693.
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B.Lee,
and
G.Vasmatzis
(1997).
Stabilization of protein structures.
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Curr Opin Biotechnol,
8,
423-428.
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S.Su,
Y.G.Gao,
H.Zhang,
T.C.Terwilliger,
and
A.H.Wang
(1997).
Analyses of the stability and function of three surface mutants (R82C, K69H, and L32R) of the gene V protein from Ff phage by X-ray crystallography.
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Protein Sci,
6,
771-780.
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PDB codes:
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M.M.Skinner,
and
T.C.Terwilliger
(1996).
Potential use of additivity of mutational effects in simplifying protein engineering.
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Proc Natl Acad Sci U S A,
93,
10753-10757.
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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
