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PDBsum entry 2fdh
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Oxidoreductase/DNA
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PDB id
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2fdh
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* Residue conservation analysis
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PDB id:
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Oxidoreductase/DNA
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Title:
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Crystal structure of alkb in complex with mn(ii), 2-oxoglutarate, and methylated trinucleotide t-mea-t
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Structure:
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5'-d(p Tp (Ma7)p T)-3'. Chain: b. Engineered: yes. Alkylated DNA repair protein alkb. Chain: a. Fragment: residues 12-216. Engineered: yes
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Source:
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Synthetic: yes. Escherichia coli k12. Organism_taxid: 83333. Strain: k-12. Gene: alkb, aidd. Expressed in: escherichia coli bl21(de3). Expression_system_taxid: 469008.
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Resolution:
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2.10Å
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R-factor:
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0.187
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R-free:
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0.228
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Authors:
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B.Yu,J.Benach,W.C.Edstrom,B.R.Gibney,J.F.Hunt,Northeast Structural Genomics Consortium (Nesg)
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Key ref:
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B.Yu
et al.
(2006).
Crystal structures of catalytic complexes of the oxidative DNA/RNA repair enzyme AlkB.
Nature,
439,
879-884.
PubMed id:
DOI:
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Date:
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14-Dec-05
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Release date:
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21-Feb-06
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PROCHECK
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Headers
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References
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P05050
(ALKB_ECOLI) -
Alpha-ketoglutarate-dependent dioxygenase AlkB from Escherichia coli (strain K12)
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Seq:
Struc:
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216 a.a.
200 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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Enzyme class:
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E.C.1.14.11.33
- Dna oxidative demethylase.
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Reaction:
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a methylated nucleobase within DNA + 2-oxoglutarate + O2 = a nucleobase within DNA + formaldehyde + succinate + CO2
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methylated nucleobase within DNA
Bound ligand (Het Group name = )
corresponds exactly
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+
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2-oxoglutarate
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+
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O2
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=
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nucleobase within DNA
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+
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formaldehyde
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+
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succinate
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+
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CO2
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Cofactor:
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Fe cation
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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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Nature
439:879-884
(2006)
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PubMed id:
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Crystal structures of catalytic complexes of the oxidative DNA/RNA repair enzyme AlkB.
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B.Yu,
W.C.Edstrom,
J.Benach,
Y.Hamuro,
P.C.Weber,
B.R.Gibney,
J.F.Hunt.
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ABSTRACT
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Nucleic acid damage by environmental and endogenous alkylation reagents creates
lesions that are both mutagenic and cytotoxic, with the latter effect accounting
for their widespread use in clinical cancer chemotherapy. Escherichia coli AlkB
and the homologous human proteins ABH2 and ABH3 (refs 5, 7) promiscuously repair
DNA and RNA bases damaged by S(N)2 alkylation reagents, which attach
hydrocarbons to endocyclic ring nitrogen atoms (N1 of adenine and guanine and N3
of thymine and cytosine). Although the role of AlkB in DNA repair has long been
established based on phenotypic studies, its exact biochemical activity was only
elucidated recently after sequence profile analysis revealed it to be a member
of the Fe-oxoglutarate-dependent dioxygenase superfamily. These enzymes use an
Fe(II) cofactor and 2-oxoglutarate co-substrate to oxidize organic substrates.
AlkB hydroxylates an alkylated nucleotide base to produce an unstable product
that releases an aldehyde to regenerate the unmodified base. Here we have
determined crystal structures of substrate and product complexes of E. coli AlkB
at resolutions from 1.8 to 2.3 A. Whereas the Fe-2-oxoglutarate dioxygenase core
matches that in other superfamily members, a unique subdomain holds a methylated
trinucleotide substrate into the active site through contacts to the
polynucleotide backbone. Amide hydrogen exchange studies and crystallographic
analyses suggest that this substrate-binding 'lid' is conformationally flexible,
which may enable docking of diverse alkylated nucleotide substrates in optimal
catalytic geometry. Different crystal structures show open and closed states of
a tunnel putatively gating O2 diffusion into the active site. Exposing crystals
of the anaerobic Michaelis complex to air yields slow but substantial oxidation
of 2-oxoglutarate that is inefficiently coupled to nucleotide oxidation. These
observations suggest that protein dynamics modulate redox chemistry and that a
hypothesized migration of the reactive oxy-ferryl ligand on the catalytic Fe ion
may be impeded when the protein is constrained in the crystal lattice.
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Selected figure(s)
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Figure 1.
Figure 1: Crystal structure of the anaerobic Michaelis complex
of E. coli AlkB- Delta- N11
with Fe(ii), 2OG and a methylated trinucleotide. a, Stereo
ribbon diagram with the backbone coloured and the 2 structural
elements labelled according to subdomain organization (with the
N-terminal extension (N) in yellow, nucleotide-recognition lid
(L) in blue, and catalytic core (C) in green as in the
sequence-structure alignment in Supplementary Fig. S2A). Most of
the blue segment is protected against amide H/D exchange by
dT-(1-me-dA)-dT substrate binding (Supplementary Fig. S2A). The
sphere representing the Fe cofactor is coloured orange, whereas
atoms in 2OG and dT-(1-me-dA)-dT are coloured according to
atomic identity (carbon, white; oxygen, red; nitrogen, blue; and
phosphorous, orange). Invariant side chains in Fe-2OG
dioxygenases are coloured red or magenta depending on whether
they interact with Fe or 2OG, respectively. b, Least-squares
superposition of 80 out of 211 C  atoms
in AlkB with a root mean square deviation of 2.1 with the
equivalent atoms in the taurine oxidase TauD^16 (Protein Data
Bank 1OS7; protein backbone and ligands coloured red). In TauD,
the 1-carboxylate of 2OG interacts with Fe in the alternative
geometry observed in crystal structures of some Fe-2OG
dioxygenases before O[2]-analogue binding18.
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Figure 3.
Figure 3: Stereo pairs showing active site stereochemistry in
alternative ligand complexes of AlkB- Delta-N11.
Ligands and side chains are coloured according to atomic
identity as in Fig. 1. a, The anaerobic Michaelis complex has
all of the octahedral coordination sites on the Fe cofactor
occupied by protein or 2OG atoms except for a single site
occupied by a crystallographic water, which must be replaced by
O[2] to initiate oxidation (Supplementary Fig. S1). b,
Equivalent view of the structure co-crystallized with Fe,
succinate and dT-(1-me-dA)-dT (Supplementary Table S2). c,
Equivalent view of the structure in which the anaerobic
Michaelis complex was exposed to oxygen for 2 h. Unbiased
electron density maps (Supplementary Fig. S5B) and occupancy
refinement (Supplementary Table S3) both support the conclusion
that most of the 2OG has been oxidized to succinate but that the
adenine base remains largely methylated after short-term in situ
oxidation. The alternative ligands are shown in semi-transparent
rendering with the degree of transparency scaled according to
refined occupancy. d, Refined 2F[o] - F[c] (green) and F[o] -
F[c] (red) electron density maps for the structure shown in c
contoured at +1  and
-3 ,
respectively. There are no F[o] - F[c] peaks  +
3 in
this region.
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The above figures are
reprinted
by permission from Macmillan Publishers Ltd:
Nature
(2006,
439,
879-884)
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.Yi,
B.Chen,
B.Qi,
W.Zhang,
G.Jia,
L.Zhang,
C.J.Li,
A.R.Dinner,
C.G.Yang,
and
C.He
(2012).
Duplex interrogation by a direct DNA repair protein in search of base damage.
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Nat Struct Mol Biol,
19,
671-676.
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PDB codes:
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E.R.Farquhar,
J.P.Emerson,
K.D.Koehntop,
M.F.Reynolds,
M.Trmčić,
and
L.Que
(2011).
In vivo self-hydroxylation of an iron-substituted manganese-dependent extradiol cleaving catechol dioxygenase.
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J Biol Inorg Chem,
16,
589-597.
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L.G.Bjørnstad,
G.Zoppellaro,
A.B.Tomter,
P...Falnes,
and
K.K.Andersson
(2011).
Spectroscopic and magnetic studies of wild-type and mutant forms of the Fe(II)- and 2-oxoglutarate-dependent decarboxylase ALKBH4.
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Biochem J,
434,
391-398.
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B.Chen,
H.Liu,
X.Sun,
and
C.G.Yang
(2010).
Mechanistic insight into the recognition of single-stranded and double-stranded DNA substrates by ABH2 and ABH3.
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Mol Biosyst,
6,
2143-2149.
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C.Yi,
G.Jia,
G.Hou,
Q.Dai,
W.Zhang,
G.Zheng,
X.Jian,
C.G.Yang,
Q.Cui,
and
C.He
(2010).
Iron-catalysed oxidation intermediates captured in a DNA repair dioxygenase.
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Nature,
468,
330-333.
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PDB codes:
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D.Li,
J.C.Delaney,
C.M.Page,
A.S.Chen,
C.Wong,
C.L.Drennan,
and
J.M.Essigmann
(2010).
Repair of DNA Alkylation Damage by the Escherichia coli Adaptive Response Protein AlkB as Studied by ESI-TOF Mass Spectrometry.
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J Nucleic Acids,
2010,
369434.
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H.S.Kim,
H.L.Kim,
K.H.Kim,
d.o. .J.Kim,
S.J.Lee,
J.Y.Yoon,
H.J.Yoon,
H.Y.Lee,
S.B.Park,
S.J.Kim,
J.Y.Lee,
and
S.W.Suh
(2010).
Crystal structure of Tpa1 from Saccharomyces cerevisiae, a component of the messenger ribonucleoprotein complex.
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Nucleic Acids Res,
38,
2099-2110.
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PDB codes:
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P.J.Holland,
and
T.Hollis
(2010).
Structural and mutational analysis of Escherichia coli AlkB provides insight into substrate specificity and DNA damage searching.
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PLoS One,
5,
e8680.
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PDB codes:
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T.A.Müller,
K.Meek,
and
R.P.Hausinger
(2010).
Human AlkB homologue 1 (ABH1) exhibits DNA lyase activity at abasic sites.
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DNA Repair (Amst),
9,
58-65.
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V.T.Monsen,
O.Sundheim,
P.A.Aas,
M.P.Westbye,
M.M.Sousa,
G.Slupphaug,
and
H.E.Krokan
(2010).
Divergent ß-hairpins determine double-strand versus single-strand substrate recognition of human AlkB-homologues 2 and 3.
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Nucleic Acids Res,
38,
6447-6455.
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X.Hong,
J.Zang,
J.White,
C.Wang,
C.H.Pan,
R.Zhao,
R.C.Murphy,
S.Dai,
P.Henson,
J.W.Kappler,
J.Hagman,
and
G.Zhang
(2010).
Interaction of JMJD6 with single-stranded RNA.
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Proc Natl Acad Sci U S A,
107,
14568-14572.
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PDB codes:
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Z.Han,
T.Niu,
J.Chang,
X.Lei,
M.Zhao,
Q.Wang,
W.Cheng,
J.Wang,
Y.Feng,
and
J.Chai
(2010).
Crystal structure of the FTO protein reveals basis for its substrate specificity.
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Nature,
464,
1205-1209.
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PDB code:
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B.Yu,
and
J.F.Hunt
(2009).
Enzymological and structural studies of the mechanism of promiscuous substrate recognition by the oxidative DNA repair enzyme AlkB.
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Proc Natl Acad Sci U S A,
106,
14315-14320.
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PDB codes:
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C.G.Yang,
K.Garcia,
and
C.He
(2009).
Damage detection and base flipping in direct DNA alkylation repair.
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Chembiochem,
10,
417-423.
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C.Yi,
C.G.Yang,
and
C.He
(2009).
A non-heme iron-mediated chemical demethylation in DNA and RNA.
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Acc Chem Res,
42,
519-529.
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E.van den Born,
A.Bekkelund,
M.N.Moen,
M.V.Omelchenko,
A.Klungland,
and
P...Falnes
(2009).
Bioinformatics and functional analysis define four distinct groups of AlkB DNA-dioxygenases in bacteria.
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Nucleic Acids Res,
37,
7124-7136.
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L.M.Iyer,
M.Tahiliani,
A.Rao,
and
L.Aravind
(2009).
Prediction of novel families of enzymes involved in oxidative and other complex modifications of bases in nucleic acids.
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Cell Cycle,
8,
1698-1710.
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M.K.Koski,
R.Hieta,
M.Hirsilä,
A.Rönkä,
J.Myllyharju,
and
R.K.Wierenga
(2009).
The crystal structure of an algal prolyl 4-hydroxylase complexed with a proline-rich peptide reveals a novel buried tripeptide binding motif.
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J Biol Chem,
284,
25290-25301.
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PDB code:
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S.Leitgeb,
G.D.Straganz,
and
B.Nidetzky
(2009).
Functional characterization of an orphan cupin protein from Burkholderia xenovorans reveals a mononuclear nonheme Fe2+-dependent oxygenase that cleaves beta-diketones.
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FEBS J,
276,
5983-5997.
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S.Schneider,
S.Schorr,
and
T.Carell
(2009).
Crystal structure analysis of DNA lesion repair and tolerance mechanisms.
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Curr Opin Struct Biol,
19,
87-95.
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V.Cetica,
L.Genitori,
L.Giunti,
M.Sanzo,
G.Bernini,
M.Massimino,
and
I.Sardi
(2009).
Pediatric brain tumors: mutations of two dioxygenases (hABH2 and hABH3) that directly repair alkylation damage.
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J Neurooncol,
94,
195-201.
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B.Bleijlevens,
T.Shivarattan,
E.Flashman,
Y.Yang,
P.J.Simpson,
P.Koivisto,
B.Sedgwick,
C.J.Schofield,
and
S.J.Matthews
(2008).
Dynamic states of the DNA repair enzyme AlkB regulate product release.
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EMBO Rep,
9,
872-877.
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C.G.Yang,
C.Yi,
E.M.Duguid,
C.T.Sullivan,
X.Jian,
P.A.Rice,
and
C.He
(2008).
Crystal structures of DNA/RNA repair enzymes AlkB and ABH2 bound to dsDNA.
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Nature,
452,
961-965.
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PDB codes:
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E.Flashman,
E.A.Bagg,
R.Chowdhury,
J.Mecinović,
C.Loenarz,
M.A.McDonough,
K.S.Hewitson,
and
C.J.Schofield
(2008).
Kinetic rationale for selectivity toward N- and C-terminal oxygen-dependent degradation domain substrates mediated by a loop region of hypoxia-inducible factor prolyl hydroxylases.
|
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J Biol Chem,
283,
3808-3815.
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E.van den Born,
M.V.Omelchenko,
A.Bekkelund,
V.Leihne,
E.V.Koonin,
V.V.Dolja,
and
P...Falnes
(2008).
Viral AlkB proteins repair RNA damage by oxidative demethylation.
|
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Nucleic Acids Res,
36,
5451-5461.
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G.Jia,
C.G.Yang,
S.Yang,
X.Jian,
C.Yi,
Z.Zhou,
and
C.He
(2008).
Oxidative demethylation of 3-methylthymine and 3-methyluracil in single-stranded DNA and RNA by mouse and human FTO.
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FEBS Lett,
582,
3313-3319.
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J.C.Delaney,
and
J.M.Essigmann
(2008).
Biological properties of single chemical-DNA adducts: a twenty year perspective.
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Chem Res Toxicol,
21,
232-252.
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J.M.Simmons,
T.A.Müller,
and
R.P.Hausinger
(2008).
Fe(II)/alpha-ketoglutarate hydroxylases involved in nucleobase, nucleoside, nucleotide, and chromatin metabolism.
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Dalton Trans,
(),
5132-5142.
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K.Helbig,
C.Grosse,
and
D.H.Nies
(2008).
Cadmium toxicity in glutathione mutants of Escherichia coli.
|
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J Bacteriol,
190,
5439-5454.
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M.P.Westbye,
E.Feyzi,
P.A.Aas,
C.B.Vågbø,
V.A.Talstad,
B.Kavli,
L.Hagen,
O.Sundheim,
M.Akbari,
N.B.Liabakk,
G.Slupphaug,
M.Otterlei,
and
H.E.Krokan
(2008).
Human AlkB Homolog 1 Is a Mitochondrial Protein That Demethylates 3-Methylcytosine in DNA and RNA.
|
| |
J Biol Chem,
283,
25046-25056.
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P.C.Bruijnincx,
G.van Koten,
and
R.J.Klein Gebbink
(2008).
Mononuclear non-heme iron enzymes with the 2-His-1-carboxylate facial triad: recent developments in enzymology and modeling studies.
|
| |
Chem Soc Rev,
37,
2716-2744.
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P.Hahn,
J.Böse,
S.Edler,
and
A.Lengeling
(2008).
Genomic structure and expression of Jmjd6 and evolutionary analysis in the context of related JmjC domain containing proteins.
|
| |
BMC Genomics,
9,
293.
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C.Mathevon,
F.Pierrel,
J.L.Oddou,
R.Garcia-Serres,
G.Blondin,
J.M.Latour,
S.Ménage,
S.Gambarelli,
M.Fontecave,
and
M.Atta
(2007).
tRNA-modifying MiaE protein from Salmonella typhimurium is a nonheme diiron monooxygenase.
|
| |
Proc Natl Acad Sci U S A,
104,
13295-13300.
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K.S.Hewitson,
B.M.Liénard,
M.A.McDonough,
I.J.Clifton,
D.Butler,
A.S.Soares,
N.J.Oldham,
L.A.McNeill,
and
C.J.Schofield
(2007).
Structural and mechanistic studies on the inhibition of the hypoxia-inducible transcription factor hydroxylases by tricarboxylic acid cycle intermediates.
|
| |
J Biol Chem,
282,
3293-3301.
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PDB codes:
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L.E.Frick,
J.C.Delaney,
C.Wong,
C.L.Drennan,
and
J.M.Essigmann
(2007).
Alleviation of 1,N6-ethanoadenine genotoxicity by the Escherichia coli adaptive response protein AlkB.
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| |
Proc Natl Acad Sci U S A,
104,
755-760.
|
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L.Sanchez-Pulido,
and
M.A.Andrade-Navarro
(2007).
The FTO (fat mass and obesity associated) gene codes for a novel member of the non-heme dioxygenase superfamily.
|
| |
BMC Biochem,
8,
23.
|
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M.K.Koski,
R.Hieta,
C.Böllner,
K.I.Kivirikko,
J.Myllyharju,
and
R.K.Wierenga
(2007).
The active site of an algal prolyl 4-hydroxylase has a large structural plasticity.
|
| |
J Biol Chem,
282,
37112-37123.
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PDB codes:
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V.Purpero,
and
G.R.Moran
(2007).
The diverse and pervasive chemistries of the alpha-keto acid dependent enzymes.
|
| |
J Biol Inorg Chem,
12,
587-601.
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W.A.Hendrickson
(2007).
Impact of structures from the protein structure initiative.
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| |
Structure,
15,
1528-1529.
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X.Cheng,
and
X.Zhang
(2007).
Structural dynamics of protein lysine methylation and demethylation.
|
| |
Mutat Res,
618,
102-115.
|
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|
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|
Z.Yu,
P.A.Genest,
B.ter Riet,
K.Sweeney,
C.DiPaolo,
R.Kieft,
E.Christodoulou,
A.Perrakis,
J.M.Simmons,
R.P.Hausinger,
H.G.van Luenen,
D.J.Rigden,
R.Sabatini,
and
P.Borst
(2007).
The protein that binds to DNA base J in trypanosomatids has features of a thymidine hydroxylase.
|
| |
Nucleic Acids Res,
35,
2107-2115.
|
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J.Ringvoll,
L.M.Nordstrand,
C.B.Vågbø,
V.Talstad,
K.Reite,
P.A.Aas,
K.H.Lauritzen,
N.B.Liabakk,
A.Bjørk,
R.W.Doughty,
P...Falnes,
H.E.Krokan,
and
A.Klungland
(2006).
Repair deficient mice reveal mABH2 as the primary oxidative demethylase for repairing 1meA and 3meC lesions in DNA.
|
| |
EMBO J,
25,
2189-2198.
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O.Sundheim,
C.B.Vågbø,
M.Bjørås,
M.M.Sousa,
V.Talstad,
P.A.Aas,
F.Drabløs,
H.E.Krokan,
J.A.Tainer,
and
G.Slupphaug
(2006).
Human ABH3 structure and key residues for oxidative demethylation to reverse DNA/RNA damage.
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| |
EMBO J,
25,
3389-3397.
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PDB code:
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T.A.Müller,
M.I.Zavodszky,
M.Feig,
L.A.Kuhn,
and
R.P.Hausinger
(2006).
Structural basis for the enantiospecificities of R- and S-specific phenoxypropionate/alpha-ketoglutarate dioxygenases.
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| |
Protein Sci,
15,
1356-1368.
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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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