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* Residue conservation analysis
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PDB id:
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Transcription/DNA
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Title:
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Crystal structure of bzip transcription factor pap1 bound to DNA
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Structure:
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DNA (5'-d( Ap Gp Gp Tp Tp Ap Cp Gp Tp Ap Ap Cp C)-3'). Chain: a, b, c, d. Engineered: yes. Transcription factor pap1. Chain: e, f, g, h, i, j. Fragment: leucine zipper domain. Synonym: ap-1-like transcription factor. Engineered: yes
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Source:
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Synthetic: yes. Schizosaccharomyces pombe. Fission yeast. Organism_taxid: 4896. Expressed in: escherichia coli. Expression_system_taxid: 562.
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Resolution:
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2.00Å
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R-factor:
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0.230
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R-free:
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0.253
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Authors:
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Y.Fujii,T.Shimizu,T.Toda,M.Yanagida,T.Hakoshima
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Key ref:
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Y.Fujii
et al.
(2000).
Structural basis for the diversity of DNA recognition by bZIP transcription factors.
Nat Struct Biol,
7,
889-893.
PubMed id:
DOI:
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Date:
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25-Aug-00
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Release date:
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02-Oct-00
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PROCHECK
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Headers
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References
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Q01663
(AP1_SCHPO) -
AP-1-like transcription factor from Schizosaccharomyces pombe (strain 972 / ATCC 24843)
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Seq:
Struc:
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552 a.a.
65 a.a.
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DOI no:
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Nat Struct Biol
7:889-893
(2000)
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PubMed id:
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Structural basis for the diversity of DNA recognition by bZIP transcription factors.
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Y.Fujii,
T.Shimizu,
T.Toda,
M.Yanagida,
T.Hakoshima.
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ABSTRACT
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The basic region leucine zipper (bZIP) proteins form one of the largest families
of transcription factors in eukaryotic cells. Despite relatively high homology
between the amino acid sequences of the bZIP motifs, these proteins recognize
diverse DNA sequences. Here we report the 2.0 A resolution crystal structure of
the bZIP motif of one such transcription factor, PAP1, a fission yeast AP-1-like
transcription factor that binds DNA containing the novel consensus sequence
TTACGTAA. The structure reveals how the Pap1-specific residues of the bZIP basic
region recognize the target sequence and shows that the side chain of the
invariant Asn in the bZIP motif adopts an alternative conformation in Pap1. This
conformation, which is stabilized by a Pap1-specific residue and its associated
water molecule, recognizes a different base in the target sequence from that in
other bZIP subfamilies.
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Selected figure(s)
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Figure 3.
Figure 3. DNA recognition of the Pap1 bZIP motif. a, Stereo
view of the basic region of the Pap1 bZIP bound to the major
groove of its DNA half site. Hydrogen bonds and van der Waals
contacts between protein and DNA are indicated by solid and
dotted lines, respectively. b, Diagrams showing protein−DNA
interactions in the Pap1−DNA (left) and the GCN4−DNA (right)
complexes. Each half site of the DNA is shown. Hydrogen bonds
and van der Waals contacts between protein and DNA bases are
indicated by solid and dotted black lines, respectively.
Interactions with the DNA phosphate backbones are indicated with
green lines. c, Schematic representations of DNA recognition by
the GCN4 bZIP (left), Pap1 bZIP (middle), and PHO4 bHLH (right)
motifs. The conserved amino acid side chains of the motifs that
make direct contacts with the DNA bases of the core sequences
are shown. Hydrogen bonds are indicated with broken lines and
van der Waals contacts with dotted lines. For clarity, water
mediated hydrogen bonds are omitted.
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Figure 4.
Figure 4. Details of PAP1−DNA interactions. a, Close up
view of the hydrophobic interactions (dotted lines) between Phe
93 and the two thymine methyl groups of the TT base pair step.
b, Comparison of the side chain conformational changes in the
Pap1 and GCN4 bZIP basic regions. The Pap1 side chains (yellow)
are superimposed on the GCN4 side chains (green). Hydrogen bonds
are indicated by solid lines, with the buried water molecule
bridging Gln 90 and the main chain of Asn 86. c, Close up view
of the Pap1 bZIP basic region, with the buried water molecule
bridging Gln 90 and the main chain of Asn 86. The water molecule
also forms hydrogen bonds with the DNA bases. d, Comparison of
the side chains of conserved residues of Pap1 (yellow) with the
corresponding residues of GCN4 (green).
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The above figures are
reprinted
by permission from Macmillan Publishers Ltd:
Nat Struct Biol
(2000,
7,
889-893)
copyright 2000.
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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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A.Sebé-Pedrós,
A.de Mendoza,
B.F.Lang,
B.M.Degnan,
and
I.Ruiz-Trillo
(2011).
Unexpected Repertoire of Metazoan Transcription Factors in the Unicellular Holozoan Capsaspora owczarzaki.
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Mol Biol Evol,
28,
1241-1254.
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K.Kitamura,
M.Taki,
N.Tanaka,
and
I.Yamashita
(2011).
Fission yeast Ubr1 ubiquitin ligase influences the oxidative stress response via degradation of active Pap1 bZIP transcription factor in the nucleus.
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Mol Microbiol,
80,
739-755.
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M.H.Kang,
H.J.Jung,
D.H.Hyun,
E.H.Park,
and
C.J.Lim
(2011).
Protective roles and Pap1-dependent regulation of the Schizosaccharomyces pombe spy1 gene under nitrosative and nutritional stresses.
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Mol Biol Rep,
38,
1129-1136.
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and
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(2010).
Arabidopsis thaliana transcription factors bZIP19 and bZIP23 regulate the adaptation to zinc deficiency.
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Proc Natl Acad Sci U S A,
107,
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and
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(2010).
Coevolution within a transcriptional network by compensatory trans and cis mutations.
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Genome Res,
20,
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A.Finkler,
and
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Mol Plant,
3,
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Y.Pan,
and
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Lysine120 interactions with p53 response elements can allosterically direct p53 organization.
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PLoS Comput Biol,
6,
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M.Kimura,
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Y.Kanno,
M.Yamamoto,
and
T.Tanaka
(2009).
Structural basis of alternative DNA recognition by Maf transcription factors.
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Mol Cell Biol,
29,
6232-6244.
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PDB code:
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J.Vyas,
M.R.Gryk,
and
M.R.Schiller
(2009).
VENN, a tool for titrating sequence conservation onto protein structures.
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Nucleic Acids Res,
37,
e124.
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M.Miller
(2009).
The importance of being flexible: the case of basic region leucine zipper transcriptional regulators.
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Curr Protein Pept Sci,
10,
244-269.
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O.Etxebeste,
E.Herrero-García,
L.Araújo-Bazán,
A.B.Rodríguez-Urra,
A.Garzia,
U.Ugalde,
and
E.A.Espeso
(2009).
The bZIP-type transcription factor FlbB regulates distinct morphogenetic stages of colony formation in Aspergillus nidulans.
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Mol Microbiol,
73,
775-789.
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|
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S.H.Song,
B.M.Kim,
C.J.Lim,
Y.S.Song,
and
E.H.Park
(2009).
Expression of the atf1+ gene is upregulated in fission yeast under nitrosative and nutritional stresses.
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Can J Microbiol,
55,
1323-1327.
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Z.Q.Tang,
H.H.Lin,
H.L.Zhang,
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and
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(2009).
Prediction of functional class of proteins and peptides irrespective of sequence homology by support vector machines.
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Bioinform Biol Insights,
1,
19-47.
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D.Chen,
C.R.Wilkinson,
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W.M.Toone,
N.Jones,
and
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(2008).
Multiple pathways differentially regulate global oxidative stress responses in fission yeast.
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Mol Biol Cell,
19,
308-317.
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G.Y.Kang,
E.H.Park,
and
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(2008).
Molecular cloning, characterization and regulation of a peroxiredoxin gene from Schizosaccharomyces pombe.
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Mol Biol Rep,
35,
387-395.
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M.Sansó,
M.Gogol,
J.Ayté,
C.Seidel,
and
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(2008).
Transcription factors Pcr1 and Atf1 have distinct roles in stress- and Sty1-dependent gene regulation.
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Eukaryot Cell,
7,
826-835.
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A.V.Morozov,
and
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Connecting protein structure with predictions of regulatory sites.
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Proc Natl Acad Sci U S A,
104,
7068-7073.
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and
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DISPLAR: an accurate method for predicting DNA-binding sites on protein surfaces.
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Nucleic Acids Res,
35,
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and
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Regulatory Module Network of bHLH Transcription Factors in Mouse Brain.
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Genome Biol,
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K.Takács,
Z.Gazdag,
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and
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Gene expressions and enzyme analyses in the Schizosaccharomyces pombe Deltapap1 transcription factor mutant exposed to Cd(2+).
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J Basic Microbiol,
47,
74-83.
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E.H.Park,
and
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(2007).
Protective role and regulation of Rad9 from the fission yeast Schizosaccharomyces pombe.
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FEMS Microbiol Lett,
275,
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M.J.Kim,
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and
M.C.Suh
(2007).
The SebHLH transcription factor mediates trans-activation of the SeFAD2 gene promoter through binding to E- and G-box elements.
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Plant Mol Biol,
64,
453-466.
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S.J.Kim,
E.M.Jung,
H.J.Jung,
Y.S.Song,
E.H.Park,
and
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(2007).
Cellular functions and transcriptional regulation of a third thioredoxin from Schizosaccharomyces pombe.
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Can J Microbiol,
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B.Miotto,
and
K.Struhl
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Differential gene regulation by selective association of transcriptional coactivators and bZIP DNA-binding domains.
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26,
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F.Baudin,
M.Moulin,
J.B.Artero,
and
C.W.Müller
(2006).
Structural basis of lytic cycle activation by the Epstein-Barr virus ZEBRA protein.
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Mol Cell,
21,
565-572.
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PDB codes:
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G.D.Amoutzias,
E.Bornberg-Bauer,
S.G.Oliver,
and
D.L.Robertson
(2006).
Reduction/oxidation-phosphorylation control of DNA binding in the bZIP dimerization network.
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BMC Genomics,
7,
107.
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M.K.Yoon,
J.Shin,
G.Choi,
and
B.S.Choi
(2006).
Intrinsically unstructured N-terminal domain of bZIP transcription factor HY5.
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Proteins,
65,
856-866.
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N.C.Cho,
H.J.Kang,
H.W.Lim,
B.C.Kim,
E.H.Park,
and
C.J.Lim
(2006).
Stress-dependent regulation of Pbh1, a BIR domain-containing protein, in the fission yeast.
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Can J Microbiol,
52,
1261-1265.
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R.Zadmard,
and
T.Schrader
(2006).
DNA recognition with large calixarene dimers.
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Angew Chem Int Ed Engl,
45,
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S.J.Kim,
Y.S.Choi,
H.G.Kim,
E.H.Park,
and
C.J.Lim
(2006).
Cloning, characterization and regulation of a protein disulfide isomerase from the fission yeast Schizosaccharomyces pombe.
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Mol Biol Rep,
33,
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A.R.Kimmel,
and
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Breaking symmetries: regulation of Dictyostelium development through chemoattractant and morphogen signal-response.
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Curr Opin Genet Dev,
14,
540-549.
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H.J.Park,
H.W.Lim,
K.Kim,
I.H.Kim,
E.H.Park,
and
C.J.Lim
(2004).
Characterization and regulation of the gamma-glutamyl transpeptidase gene from the fission yeast Schizosaccharomyces pombe.
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Can J Microbiol,
50,
61-66.
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S.Dai,
Z.Zhang,
S.Chen,
and
R.N.Beachy
(2004).
RF2b, a rice bZIP transcription activator, interacts with RF2a and is involved in symptom development of rice tungro disease.
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Proc Natl Acad Sci U S A,
101,
687-692.
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S.M.Hong,
H.W.Lim,
I.H.Kim,
K.Kim,
E.H.Park,
and
C.J.Lim
(2004).
Stress-dependent regulation of the gene encoding thioredoxin reductase from the fission yeast.
|
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FEMS Microbiol Lett,
234,
379-385.
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M.Miller,
J.D.Shuman,
T.Sebastian,
Z.Dauter,
and
P.F.Johnson
(2003).
Structural basis for DNA recognition by the basic region leucine zipper transcription factor CCAAT/enhancer-binding protein alpha.
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J Biol Chem,
278,
15178-15184.
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PDB code:
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S.Dai,
S.Petruccelli,
M.I.Ordiz,
Z.Zhang,
S.Chen,
and
R.N.Beachy
(2003).
Functional analysis of RF2a, a rice transcription factor.
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J Biol Chem,
278,
36396-36402.
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V.Ramirez-Carrozzi,
and
T.Kerppola
(2003).
Asymmetric recognition of nonconsensus AP-1 sites by Fos-Jun and Jun-Jun influences transcriptional cooperativity with NFAT1.
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A.Acharya,
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J.R.Moll,
and
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(2002).
Classification of human B-ZIP proteins based on dimerization properties.
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C.Vinson,
and
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Magnesium is required for specific DNA binding of the CREB B-ZIP domain.
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and
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(2002).
The crystal structure of the C-terminal fragment of striated-muscle alpha-tropomyosin reveals a key troponin T recognition site.
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Proc Natl Acad Sci U S A,
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PDB code:
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M.Pinak
(2001).
Molecular dynamics simulation of thymine glycol-lesioned DNA reveals specific hydration at the lesion.
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Impact of CpG methylation on structure, dynamics and solvation of cAMP DNA responsive element.
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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
code is
shown on the right.
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Links
