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PDBsum entry 2co0
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Transcription
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PDB id
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2co0
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Contents |
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* Residue conservation analysis
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PDB id:
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| Name: |
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Transcription
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Title:
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Wdr5 and unmodified histone h3 complex at 2.25 angstrom
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Structure:
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Wd-repeat protein 5. Chain: a. Fragment: residues 20-334. Synonym: bmp2-induced 3-kb gene protein. Engineered: yes. Histone h3 dimethyl-lysine 4. Chain: b, d. Fragment: histone tail, unp residues 2-16. Engineered: yes.
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Source:
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Homo sapiens. Human. Organism_taxid: 9606. Expressed in: escherichia coli bl21(de3). Expression_system_taxid: 469008. Expression_system_variant: rosetta2 plyss. Synthetic: yes. Expression_system_variant: rosetta2 plyss
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Biol. unit:
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Dimer (from PDB file)
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Resolution:
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2.25Å
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R-factor:
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0.190
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R-free:
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0.226
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Authors:
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A.J.Ruthenburg,W.Wang,D.M.Graybosch,H.Li,C.D.Allis,D.J.Patel, G.L.Verdine
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Key ref:
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A.J.Ruthenburg
et al.
(2006).
Histone H3 recognition and presentation by the WDR5 module of the MLL1 complex.
Nat Struct Mol Biol,
13,
704-712.
PubMed id:
DOI:
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Date:
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25-May-06
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Release date:
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03-Jul-06
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PROCHECK
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Headers
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References
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P61964
(WDR5_HUMAN) -
WD repeat-containing protein 5 from Homo sapiens
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Seq:
Struc:
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334 a.a.
304 a.a.*
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Key: |
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PfamA domain |
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Secondary structure |
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CATH domain |
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*
PDB and UniProt seqs differ
at 4 residue positions (black
crosses)
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DOI no:
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Nat Struct Mol Biol
13:704-712
(2006)
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PubMed id:
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Histone H3 recognition and presentation by the WDR5 module of the MLL1 complex.
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A.J.Ruthenburg,
W.Wang,
D.M.Graybosch,
H.Li,
C.D.Allis,
D.J.Patel,
G.L.Verdine.
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ABSTRACT
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WDR5 is a core component of SET1-family complexes that achieve transcriptional
activation via methylation of histone H3 on Nzeta of Lys4 (H3K4). The role of
WDR5 in the MLL1 complex has recently been described as specific recognition of
dimethyl-K4 in the context of a histone H3 amino terminus; WDR5 is essential for
vertebrate development, Hox gene activation and global H3K4 trimethylation. We
report the high-resolution X-ray structures of WDR5 in the unliganded form and
complexed with histone H3 peptides having unmodified and mono-, di- and
trimethylated K4, which together provide the first comprehensive analysis of
methylated histone recognition by the ubiquitous WD40-repeat fold. Contrary to
predictions, the structures reveal that WDR5 does not read out the methylation
state of K4 directly, but instead serves to present the K4 side chain for
further methylation by SET1-family complexes.
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Selected figure(s)
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Figure 3.
Figure 3. Peptide recognition by WDR5 and conformational changes
upon peptide binding. (a) The peptide is recognized by an
elaborate series of direct and indirect contacts. Orientation of
the peptide–WDR5 complex is the same as in the lower panel of
Figure 1c. The majority of direct contacts from WDR5 are made to
the N terminus and the first three residues. These residues
adopt an approximately helical main chain conformation, with one
hydrogen bond between the A1 and K4 backbone. Water-mediated
contacts are important in recognition of the C-terminal residues
of the peptide, as all waters shown (red spheres) are conserved
among the peptide-bound structures. Tyr191 apparently acts as a
central platform in this peptide-bound water network. (b) Phe133
and Phe263 form an aromatic sandwich about the R2 guanidinium
moiety, equatorially flanked by a number of backbone
carbonyl–mediated hydrogen bonds. These tight hydrogen bonds
are thought to impart specificity for arginine over
dimethyllysine, particularly the one from N  of
R2 to the Ser91 carbonyl. (c) Apparent coordinated movement of
Phe133 and Phe149 to form the top of the aromatic sandwich
recognition element when peptide is bound. The relevant
apostructure side chains are depicted in gray and a
representative liganded structure (H3K4me2 complex I) is in
crimson. (d) Retraction of the loop bearing Lys259 causes a
reorganization of the residues lining the central cavity, which
permits tight R2 coordination. Coloring is as in c. This
movement may be driven by a steric clash between this lysine and
the incoming peptide Q5 side chain.
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Figure 5.
Figure 5. Differences in K4 conformation in the different
methylation states. (a–d) The crystal-packing interface
relevant to K4 conformation is depicted for the H3K4me3 complex
(C2 space group, a), H3K4me2 complex I (C2, b), H3K4me1 complex
(C2, c) and unmodified H3 complex (P2[1], d). Peptides are
colored as in Figure 2b; the principal WDR5 protomer is red; and
the symmetry-related protomer at the peptide interface is gray.
Note the rotation about  3
moving from the tri- and dimethylated species to the
monomethylated and unmodified species. In H3K4me2 complex I, the
distances between the  -methyl
carbons and the Glu322 carboxylate O  1
are 3.27 Å and 3.37 Å for the closest methyl group
in each of the two complexes per asymmetric unit, whereas these
distances are 3.83 Å and 3.87 Å for the more distant
methyl group. For comparison, the previously reported shorter
distances for these measurements were 3.15 Å and 3.42
Å^22.
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The above figures are
reprinted
by permission from Macmillan Publishers Ltd:
Nat Struct Mol Biol
(2006,
13,
704-712)
copyright 2006.
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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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C.A.Musselman,
M.E.Lalonde,
J.Côté,
and
T.G.Kutateladze
(2012).
Perceiving the epigenetic landscape through histone readers.
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Nat Struct Mol Biol,
19,
1218-1227.
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V.Migliori,
J.Müller,
S.Phalke,
D.Low,
M.Bezzi,
W.C.Mok,
S.K.Sahu,
J.Gunaratne,
P.Capasso,
C.Bassi,
V.Cecatiello,
A.De Marco,
W.Blackstock,
V.Kuznetsov,
B.Amati,
M.Mapelli,
and
E.Guccione
(2012).
Symmetric dimethylation of H3R2 is a newly identified histone mark that supports euchromatin maintenance.
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Nat Struct Mol Biol,
19,
136-144.
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PDB code:
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C.Xu,
and
J.Min
(2011).
Structure and function of WD40 domain proteins.
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Protein Cell,
2,
202-214.
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PDB codes:
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S.Lejon,
S.Y.Thong,
A.Murthy,
S.AlQarni,
N.V.Murzina,
G.A.Blobel,
E.D.Laue,
and
J.P.Mackay
(2011).
Insights into association of the NuRD complex with FOG-1 from the crystal structure of an RbAp48·FOG-1 complex.
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J Biol Chem,
286,
1196-1203.
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PDB code:
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S.S.Oliver,
and
J.M.Denu
(2011).
Dynamic interplay between histone H3 modifications and protein interpreters: emerging evidence for a "histone language".
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Chembiochem,
12,
299-307.
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A.Tuukkanen,
B.Huang,
A.Henschel,
F.Stewart,
and
M.Schroeder
(2010).
Structural modeling of histone methyltransferase complex Set1C from Saccharomyces cerevisiae using constraint-based docking.
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Proteomics,
10,
4186-4195.
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C.M.Tate,
J.H.Lee,
and
D.G.Skalnik
(2010).
CXXC finger protein 1 restricts the Setd1A histone H3K4 methyltransferase complex to euchromatin.
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FEBS J,
277,
210-223.
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C.Xu,
C.Bian,
W.Yang,
M.Galka,
H.Ouyang,
C.Chen,
W.Qiu,
H.Liu,
A.E.Jones,
F.MacKenzie,
P.Pan,
S.S.Li,
H.Wang,
and
J.Min
(2010).
Binding of different histone marks differentially regulates the activity and specificity of polycomb repressive complex 2 (PRC2).
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Proc Natl Acad Sci U S A,
107,
19266-19271.
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PDB codes:
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H.Richly,
M.Lange,
E.Simboeck,
and
L.Di Croce
(2010).
Setting and resetting of epigenetic marks in malignant transformation and development.
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Bioessays,
32,
669-679.
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H.Xu,
J.Wang,
Q.Hu,
Y.Quan,
H.Chen,
Y.Cao,
C.Li,
Y.Wang,
and
Q.He
(2010).
DCAF26, an adaptor protein of Cul4-based E3, is essential for DNA methylation in Neurospora crassa.
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PLoS Genet,
6,
0.
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J.R.England,
J.Huang,
M.J.Jennings,
R.D.Makde,
and
S.Tan
(2010).
RCC1 uses a conformationally diverse loop region to interact with the nucleosome: a model for the RCC1-nucleosome complex.
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J Mol Biol,
398,
518-529.
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K.I.Ansari,
and
S.S.Mandal
(2010).
Mixed lineage leukemia: roles in gene expression, hormone signaling and mRNA processing.
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FEBS J,
277,
1790-1804.
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|
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L.Cui,
and
J.Miao
(2010).
Chromatin-mediated epigenetic regulation in the malaria parasite Plasmodium falciparum.
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Eukaryot Cell,
9,
1138-1149.
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M.S.Cosgrove,
and
A.Patel
(2010).
Mixed lineage leukemia: a structure-function perspective of the MLL1 protein.
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FEBS J,
277,
1832-1842.
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M.Vedadi,
C.H.Arrowsmith,
A.Allali-Hassani,
G.Senisterra,
and
G.A.Wasney
(2010).
Biophysical characterization of recombinant proteins: a key to higher structural genomics success.
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J Struct Biol,
172,
107-119.
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V.Limviphuvadh,
L.L.Chua,
R.A.Rahim,
F.Eisenhaber,
S.Maurer-Stroh,
and
S.Adhikari
(2010).
Similarity of molecular phenotype between known epilepsy gene LGI1 and disease candidate gene LGI2.
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BMC Biochem,
11,
39.
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C.Bach,
and
R.K.Slany
(2009).
Molecular pathology of mixed-lineage leukemia.
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Future Oncol,
5,
1271-1281.
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M.Hirst,
and
M.A.Marra
(2009).
Epigenetics and human disease.
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Int J Biochem Cell Biol,
41,
136-146.
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R.C.Trievel,
and
A.Shilatifard
(2009).
WDR5, a complexed protein.
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Nat Struct Mol Biol,
16,
678-680.
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R.K.Slany
(2009).
The molecular biology of mixed lineage leukemia.
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Haematologica,
94,
984-993.
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S.S.Ng,
W.W.Yue,
U.Oppermann,
and
R.J.Klose
(2009).
Dynamic protein methylation in chromatin biology.
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Cell Mol Life Sci,
66,
407-422.
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A.N.Iberg,
A.Espejo,
D.Cheng,
D.Kim,
J.Michaud-Levesque,
S.Richard,
and
M.T.Bedford
(2008).
Arginine methylation of the histone h3 tail impedes effector binding.
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J Biol Chem,
283,
3006-3010.
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A.Patel,
V.Dharmarajan,
and
M.S.Cosgrove
(2008).
Structure of WDR5 Bound to Mixed Lineage Leukemia Protein-1 Peptide.
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J Biol Chem,
283,
32158-32161.
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PDB code:
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A.Patel,
V.E.Vought,
V.Dharmarajan,
and
M.S.Cosgrove
(2008).
A Conserved Arginine-containing Motif Crucial for the Assembly and Enzymatic Activity of the Mixed Lineage Leukemia Protein-1 Core Complex.
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J Biol Chem,
283,
32162-32175.
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A.Vitaliano-Prunier,
A.Menant,
M.Hobeika,
V.Géli,
C.Gwizdek,
and
C.Dargemont
(2008).
Ubiquitylation of the COMPASS component Swd2 links H2B ubiquitylation to H3K4 trimethylation.
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Nat Cell Biol,
10,
1365-1371.
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F.Forneris,
C.Binda,
E.Battaglioli,
and
A.Mattevi
(2008).
LSD1: oxidative chemistry for multifaceted functions in chromatin regulation.
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Trends Biochem Sci,
33,
181-189.
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I.W.McKinnell,
J.Ishibashi,
F.Le Grand,
V.G.Punch,
G.C.Addicks,
J.F.Greenblatt,
F.J.Dilworth,
and
M.A.Rudnicki
(2008).
Pax7 activates myogenic genes by recruitment of a histone methyltransferase complex.
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Nat Cell Biol,
10,
77-84.
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J.H.Lee,
and
D.G.Skalnik
(2008).
Wdr82 is a C-terminal domain-binding protein that recruits the Setd1A Histone H3-Lys4 methyltransferase complex to transcription start sites of transcribed human genes.
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Mol Cell Biol,
28,
609-618.
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J.J.Song,
J.D.Garlick,
and
R.E.Kingston
(2008).
Structural basis of histone H4 recognition by p55.
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Genes Dev,
22,
1313-1318.
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PDB codes:
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J.J.Song,
and
R.E.Kingston
(2008).
WDR5 Interacts with Mixed Lineage Leukemia (MLL) Protein via the Histone H3-binding Pocket.
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J Biol Chem,
283,
35258-35264.
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PDB code:
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M.M.Brent,
and
R.Marmorstein
(2008).
Ankyrin for methylated lysines.
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Nat Struct Mol Biol,
15,
221-222.
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N.Nady,
J.Min,
M.S.Kareta,
F.Chédin,
and
C.H.Arrowsmith
(2008).
A SPOT on the chromatin landscape? Histone peptide arrays as a tool for epigenetic research.
|
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Trends Biochem Sci,
33,
305-313.
|
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N.V.Murzina,
X.Y.Pei,
W.Zhang,
M.Sparkes,
J.Vicente-Garcia,
J.V.Pratap,
S.H.McLaughlin,
T.R.Ben-Shahar,
A.Verreault,
B.F.Luisi,
and
E.D.Laue
(2008).
Structural basis for the recognition of histone H4 by the histone-chaperone RbAp46.
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Structure,
16,
1077-1085.
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PDB codes:
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T.Suganuma,
S.G.Pattenden,
and
J.L.Workman
(2008).
Diverse functions of WD40 repeat proteins in histone recognition.
|
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Genes Dev,
22,
1265-1268.
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A.J.Ruthenburg,
C.D.Allis,
and
J.Wysocka
(2007).
Methylation of lysine 4 on histone H3: intricacy of writing and reading a single epigenetic mark.
|
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Mol Cell,
25,
15-30.
|
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D.Hyllus,
C.Stein,
K.Schnabel,
E.Schiltz,
A.Imhof,
Y.Dou,
J.Hsieh,
and
U.M.Bauer
(2007).
PRMT6-mediated methylation of R2 in histone H3 antagonizes H3 K4 trimethylation.
|
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Genes Dev,
21,
3369-3380.
|
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|
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E.Guccione,
C.Bassi,
F.Casadio,
F.Martinato,
M.Cesaroni,
H.Schuchlautz,
B.Lüscher,
and
B.Amati
(2007).
Methylation of histone H3R2 by PRMT6 and H3K4 by an MLL complex are mutually exclusive.
|
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Nature,
449,
933-937.
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F.Tie,
C.A.Stratton,
R.L.Kurzhals,
and
P.J.Harte
(2007).
The N terminus of Drosophila ESC binds directly to histone H3 and is required for E(Z)-dependent trimethylation of H3 lysine 27.
|
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Mol Cell Biol,
27,
2014-2026.
|
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|
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G.Kustatscher,
and
A.G.Ladurner
(2007).
Modular paths to 'decoding' and 'wiping' histone lysine methylation.
|
| |
Curr Opin Chem Biol,
11,
628-635.
|
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M.A.Soliman,
and
K.Riabowol
(2007).
After a decade of study-ING, a PHD for a versatile family of proteins.
|
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Trends Biochem Sci,
32,
509-519.
|
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R.L.Rich,
and
D.G.Myszka
(2007).
Survey of the year 2006 commercial optical biosensor literature.
|
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J Mol Recognit,
20,
300-366.
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S.Beltran,
M.Angulo,
M.Pignatelli,
F.Serras,
and
M.Corominas
(2007).
Functional dissection of the ash2 and ash1 transcriptomes provides insights into the transcriptional basis of wing phenotypes and reveals conserved protein interactions.
|
| |
Genome Biol,
8,
R67.
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S.D.Taverna,
H.Li,
A.J.Ruthenburg,
C.D.Allis,
and
D.J.Patel
(2007).
How chromatin-binding modules interpret histone modifications: lessons from professional pocket pickers.
|
| |
Nat Struct Mol Biol,
14,
1025-1040.
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S.Lall
(2007).
Primers on chromatin.
|
| |
Nat Struct Mol Biol,
14,
1110-1115.
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T.Kouzarides
(2007).
Chromatin modifications and their function.
|
| |
Cell,
128,
693-705.
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A.Loyola,
T.Bonaldi,
D.Roche,
A.Imhof,
and
G.Almouzni
(2006).
PTMs on H3 variants before chromatin assembly potentiate their final epigenetic state.
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| |
Mol Cell,
24,
309-316.
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A.Schuetz,
A.Allali-Hassani,
F.Martín,
P.Loppnau,
M.Vedadi,
A.Bochkarev,
A.N.Plotnikov,
C.H.Arrowsmith,
and
J.Min
(2006).
Structural basis for molecular recognition and presentation of histone H3 by WDR5.
|
| |
EMBO J,
25,
4245-4252.
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PDB codes:
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Y.Dou,
T.A.Milne,
A.J.Ruthenburg,
S.Lee,
J.W.Lee,
G.L.Verdine,
C.D.Allis,
and
R.G.Roeder
(2006).
Regulation of MLL1 H3K4 methyltransferase activity by its core components.
|
| |
Nat Struct Mol Biol,
13,
713-719.
|
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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
