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666 a.a.
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133 a.a.
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16 a.a.
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* Residue conservation analysis
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PDB id:
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Oxidoreductase/repressor
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Title:
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Structural basis of lsd1-corest selectivity in histone h3 recognition
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Structure:
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Lysine-specific histone demethylase 1. Chain: a. Fragment: residues 123-852. Synonym: flavin-containing amine oxidase domain-containing protein 2, braf35-hdac complex protein bhc110. Engineered: yes. Rest corepressor 1. Chain: b. Fragment: 305-482.
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Source:
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Homo sapiens. Human. Organism_taxid: 9606. Expressed in: escherichia coli. Expression_system_taxid: 562. Synthetic: yes. Organism_taxid: 9606
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Resolution:
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3.10Å
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R-factor:
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0.224
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R-free:
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0.239
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Authors:
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F.Forneris,C.Binda,A.Adamo,E.Battaglioli,A.Mattevi
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Key ref:
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F.Forneris
et al.
(2007).
Structural basis of LSD1-CoREST selectivity in histone H3 recognition.
J Biol Chem,
282,
20070-20074.
PubMed id:
DOI:
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Date:
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23-May-07
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Release date:
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29-May-07
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PROCHECK
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Headers
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References
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O60341
(KDM1A_HUMAN) -
Lysine-specific histone demethylase 1A from Homo sapiens
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Seq:
Struc:
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852 a.a.
666 a.a.
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Enzyme class:
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Chain A:
E.C.1.14.99.66
- [histone-H3]-N(6),N(6)-dimethyl-L-lysine(4) FAD-dependent demethylase.
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Reaction:
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N6,N6-dimethyl-L-lysyl4-[histone H3] + 2 A + 2 H2O = L-lysyl4- [histone H3] + 2 formaldehyde + 2 AH2
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N(6),N(6)-dimethyl-L-lysyl(4)-[histone H3]
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+
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2
×
A
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+
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2
×
H2O
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=
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L-lysyl(4)- [histone H3]
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+
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2
×
formaldehyde
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+
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2
×
AH2
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Molecule diagrams generated from .mol files obtained from the
KEGG ftp site
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DOI no:
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J Biol Chem
282:20070-20074
(2007)
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PubMed id:
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Structural basis of LSD1-CoREST selectivity in histone H3 recognition.
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F.Forneris,
C.Binda,
A.Adamo,
E.Battaglioli,
A.Mattevi.
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ABSTRACT
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Histone demethylase LSD1 regulates transcription by demethylating Lys(4) of
histone H3. The crystal structure of the enzyme in complex with CoREST and a
substrate-like peptide inhibitor highlights an intricate network of interactions
and a folded conformation of the bound peptide. The core of the peptide
structure is formed by Arg(2), Gln(5), and Ser(10), which are engaged in
specific intramolecular H-bonds. Several charged side chains on the surface of
the substrate-binding pocket establish electrostatic interactions with the
peptide. The three-dimensional structure predicts that methylated Lys(4) binds
in a solvent inaccessible position in front of the flavin cofactor. This
geometry is fully consistent with the demethylation reaction being catalyzed
through a flavin-mediated oxidation of the substrate amino-methyl group. These
features dictate the exquisite substrate specificity of LSD1 and provide a
structural framework to explain the fine tuning of its catalytic activity and
the active role of CoREST in substrate recognition.
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Selected figure(s)
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Figure 1.
FIGURE 1. Crystal structure of LSD1-CoREST in complex with
pLys4Met H3 peptide. A, ribbon diagram of the structure. LSD1 is
in blue, CoREST in red, and the peptide in green. The FAD
cofactor is shown as a yellow ball-and-stick. The final model
consists of residues 171–836 of LSD1, residues 308–440 of
CoREST, and residues 1–16 of pLys4Met peptide. B, fitting of
the refined pLys4Met peptide in the unbiased electron density
calculated with weighted 2F[o] – F[c] coefficients. The map
was calculated prior inclusion of the peptide atoms in the
refinement calculations. The contour level is 1.2  , and
the resolution is 3.1 Å. The sequence of the histone H3
peptide used for the x-ray analysis is
^1ARTMQTARKSTGGKAPRKQLA^21.
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Figure 2.
FIGURE 2. Recognition of H3 peptide by LSD1. A, surface
view of the peptide-binding pocket. The peptide is shown in
green and the LSD1 surface in gray. Nitrogens are blue, oxygens
red, sulfurs yellow, and carbons green. The positions of
negatively charged residues lining the peptide-binding site are
labeled. The C  trace of CoREST
residues 308–314 is shown in red, highlighting their proximity
to the LSD1 372–395 -helix that is integral
part of the peptide-binding site. The orientation is the same as
in Fig. 1A. B, three-dimensional view of the peptide-binding
mode. Nitrogens are blue, oxygens red, and sulfurs yellow.
Carbons of peptide and protein residues are in green and gray,
respectively. The flavin cofactor is yellow. With respect to
Fig. 1A, the structure is rotated by  180° about the
vertical axis in the plane of the drawing. C, schematic
representation of the peptide-protein interactions. D, model of
dimethyl Lys^4 peptide substrate bound in the active site.
Orientation and atom colors are the same as described in B. The
modeling was carried out assuming that the C  -C  -C  atoms of dimethyl Lys^4
adopt the same conformation of the C -C -S atoms of pMet^4 in the
crystal structure. In this way, the predicted position of the
N-bound CH[3] group of dimethyl Lys^4 falls exactly in front of
the N-5 atom of the flavin. This type of substrate-binding
geometry is similar to that found in other flavin-dependent
oxidases and is fully consistent with an oxidative attack of the
flavin on the N–CH[3] group of the substrate leading to the
formation of an NH=CH[2] imine that is then hydrolyzed to
generate the demethylated Lys^4 and formaldehyde.
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The above figures are
reprinted
by permission from the ASBMB:
J Biol Chem
(2007,
282,
20070-20074)
copyright 2007.
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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.K.Upadhyay,
and
X.Cheng
(2011).
Dynamics of histone lysine methylation: structures of methyl writers and erasers.
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Prog Drug Res,
67,
107-124.
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E.Metzger,
A.Imhof,
D.Patel,
P.Kahl,
K.Hoffmeyer,
N.Friedrichs,
J.M.Müller,
H.Greschik,
J.Kirfel,
S.Ji,
N.Kunowska,
C.Beisenherz-Huss,
T.Günther,
R.Buettner,
and
R.Schüle
(2010).
Phosphorylation of histone H3T6 by PKCbeta(I) controls demethylation at histone H3K4.
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Nature,
464,
792-796.
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M.L.Bellows,
and
C.A.Floudas
(2010).
Computational methods for de novo protein design and its applications to the human immunodeficiency virus 1, purine nucleoside phosphorylase, ubiquitin specific protease 7, and histone demethylases.
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Curr Drug Targets,
11,
264-278.
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X.Cheng,
and
R.M.Blumenthal
(2010).
Coordinated chromatin control: structural and functional linkage of DNA and histone methylation.
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Biochemistry,
49,
2999-3008.
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Y.Lin,
Y.Wu,
J.Li,
C.Dong,
X.Ye,
Y.I.Chi,
B.M.Evers,
and
B.P.Zhou
(2010).
The SNAG domain of Snail1 functions as a molecular hook for recruiting lysine-specific demethylase 1.
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EMBO J,
29,
1803-1816.
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Y.Yang,
L.Hu,
P.Wang,
H.Hou,
Y.Lin,
Y.Liu,
Z.Li,
R.Gong,
X.Feng,
L.Zhou,
W.Zhang,
Y.Dong,
H.Yang,
H.Lin,
Y.Wang,
C.D.Chen,
and
Y.Xu
(2010).
Structural insights into a dual-specificity histone demethylase ceKDM7A from Caenorhabditis elegans.
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Cell Res,
20,
886-898.
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PDB codes:
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A.Karytinos,
F.Forneris,
A.Profumo,
G.Ciossani,
E.Battaglioli,
C.Binda,
and
A.Mattevi
(2009).
A novel mammalian flavin-dependent histone demethylase.
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J Biol Chem,
284,
17775-17782.
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B.C.Smith,
and
J.M.Denu
(2009).
Chemical mechanisms of histone lysine and arginine modifications.
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Biochim Biophys Acta,
1789,
45-57.
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F.Forneris,
E.Battaglioli,
A.Mattevi,
and
C.Binda
(2009).
New roles of flavoproteins in molecular cell biology: histone demethylase LSD1 and chromatin.
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FEBS J,
276,
4304-4312.
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F.Forneris,
R.Orru,
D.Bonivento,
L.R.Chiarelli,
and
A.Mattevi
(2009).
ThermoFAD, a Thermofluor-adapted flavin ad hoc detection system for protein folding and ligand binding.
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FEBS J,
276,
2833-2840.
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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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P.A.Cole
(2008).
Chemical probes for histone-modifying enzymes.
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Nat Chem Biol,
4,
590-597.
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G.Kustatscher,
and
A.G.Ladurner
(2007).
Modular paths to 'decoding' and 'wiping' histone lysine methylation.
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Curr Opin Chem Biol,
11,
628-635.
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J.C.Culhane,
and
P.A.Cole
(2007).
LSD1 and the chemistry of histone demethylation.
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Curr Opin Chem Biol,
11,
561-568.
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J.R.Wilson
(2007).
Targeting the JMJD2A histone lysine demethylase.
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Nat Struct Mol Biol,
14,
682-684.
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S.Lall
(2007).
Primers on chromatin.
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Nat Struct Mol Biol,
14,
1110-1115.
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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
