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PDBsum entry 2bri
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* Residue conservation analysis
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Enzyme class:
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E.C.2.7.4.22
- Ump kinase.
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Reaction:
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UMP + ATP = UDP + ADP
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UMP
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+
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ATP
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=
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UDP
Bound ligand (Het Group name = )
matches with 81.25% similarity
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+
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ADP
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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 Mol Biol
352:438-454
(2005)
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PubMed id:
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The crystal structure of Pyrococcus furiosus UMP kinase provides insight into catalysis and regulation in microbial pyrimidine nucleotide biosynthesis.
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C.Marco-Marín,
F.Gil-Ortiz,
V.Rubio.
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ABSTRACT
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UMP kinase (UMPK), the enzyme responsible for microbial UMP phosphorylation,
plays a key role in pyrimidine nucleotide biosynthesis, regulating this process
via feed-back control and via gene repression of carbamoyl phosphate synthetase
(the first enzyme of the pyrimidine biosynthesis pathway). We present crystal
structures of Pyrococcus furiosus UMPK, free or complexed with AMPPNP or AMPPNP
and UMP, at 2.4 A, 3 A and 2.55 A resolution, respectively, providing a true
snapshot of the catalytically competent bisubstrate complex. The structure
proves that UMPK does not resemble other nucleoside monophosphate kinases,
including the UMP/CMP kinase found in animals, and thus UMPK may be a potential
antimicrobial target. This enzyme has a homohexameric architecture centred
around a hollow nucleus, and is organized as a trimer of dimers. The UMPK
polypeptide exhibits the amino acid kinase family (AAKF) fold that has been
reported in carbamate kinase and acetylglutamate kinase. Comparison with
acetylglutamate kinase reveals that the substrates bind within each subunit at
equivalent, adequately adapted sites. The UMPK structure contains two bound Mg
ions, of which one helps stabilize the transition state, thus having the same
catalytic role as one lysine residue found in acetylglutamate kinase, which is
missing from P.furiosus UMPK. Relative to carbamate kinase and acetylglutamate
kinase, UMPK presents a radically different dimer architecture, lacking the
characteristic 16-stranded beta-sheet backbone that was considered a signature
of AAKF enzymes. Its hexameric architecture, also a novel trait, results from
equatorial contacts between the A and B subunits of adjacent dimers combined
with polar contacts between A or B subunits, and may be required for the UMPK
regulatory functions, such as gene regulation, proposed here to be mediated by
hexamer-hexamer interactions with the DNA-binding protein PepA.
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Selected figure(s)
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Figure 1.
Figure 1. Pyrimidine nucleotide biosynthesis and the roles of
UMPK demonstrated in Escherichia coli. Prokaryotic UMPK is
highlighted within a grey box. The eukaryotic CMP/UMPK is
included also. Multiple arrows denote multiple steps. The broken
and dotted arrows denote feed-back inhibition and activation,
respectively. The double-lined arrow indicates repression by
UMPK of the carAB genes, which encode carbamoyl phosphate
synthetase. The involvement of the DNA-binding proteins PepA and
IHF in this process is indicated. Figure 1. Pyrimidine
nucleotide biosynthesis and the roles of UMPK demonstrated in
Escherichia coli. Prokaryotic UMPK is highlighted within a grey
box. The eukaryotic CMP/UMPK is included also. Multiple arrows
denote multiple steps. The broken and dotted arrows denote
feed-back inhibition and activation, respectively. The
double-lined arrow indicates repression by UMPK of the carAB
genes, which encode carbamoyl phosphate synthetase. The
involvement of the DNA-binding proteins PepA and IHF in this
process is indicated.
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Figure 4.
Figure 4. Substrate binding in UMPK. (a) Stereo view of the
C^α trace of the substrate-binding sites, with bound
Mg[2]AMPPNP and UMP coloured. Amino acid side-chains are also in
colour, in thinner trace. (b) Stereoscopic detailed
representation of the phosphoryl group transfer site in the
complex with Mg[2]AMPPNP and UMP. Mg ions and water molecules
are drawn as purple and cyan spheres, respectively. Nearby
protein residues are shown in thinner trace. Hydrogen bonds and
coordination bonds with Mg are shown as red lines, indicating
the interatomic distances (in Å). The interatomic distance
between the attacking O atom of UMP and the γ-P atom is
represented with a blue line. (c) and (d) Plots of the
interactions between the protein and (c) UMP or (d) Mg[2]AMPPNP
in the ternary complex. The letter W denotes a water molecule.
Distances are in Å. Figure 4. Substrate binding in
UMPK. (a) Stereo view of the C^α trace of the substrate-binding
sites, with bound Mg[2]AMPPNP and UMP coloured. Amino acid
side-chains are also in colour, in thinner trace. (b)
Stereoscopic detailed representation of the phosphoryl group
transfer site in the complex with Mg[2]AMPPNP and UMP. Mg ions
and water molecules are drawn as purple and cyan spheres,
respectively. Nearby protein residues are shown in thinner
trace. Hydrogen bonds and coordination bonds with Mg are shown
as red lines, indicating the interatomic distances (in Å).
The interatomic distance between the attacking O atom of UMP and
the γ-P atom is represented with a blue line. (c) and (d) Plots
of the interactions between the protein and (c) UMP or (d)
Mg[2]AMPPNP in the ternary complex. The letter W denotes a water
molecule. Distances are in Å. Parts (c) and (d) were drawn
with LIGPLOT.[3]^50
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The above figures are
reprinted
by permission from Elsevier:
J Mol Biol
(2005,
352,
438-454)
copyright 2005.
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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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G.Labesse,
K.Benkali,
I.Salard-Arnaud,
A.M.Gilles,
and
H.Munier-Lehmann
(2011).
Structural and functional characterization of the Mycobacterium tuberculosis uridine monophosphate kinase: insights into the allosteric regulation.
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Nucleic Acids Res,
39,
3458-3472.
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PDB code:
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E.Marcos,
R.Crehuet,
and
I.Bahar
(2010).
On the conservation of the slow conformational dynamics within the amino acid kinase family: NAGK the paradigm.
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PLoS Comput Biol,
6,
e1000738.
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N.Dellas,
and
J.P.Noel
(2010).
Mutation of archaeal isopentenyl phosphate kinase highlights mechanism and guides phosphorylation of additional isoprenoid monophosphates.
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ACS Chem Biol,
5,
589-601.
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PDB codes:
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P.l.e. .M.Nguyen,
I.Bervoets,
D.Maes,
and
D.Charlier
(2010).
The protein-DNA contacts in RutR•carAB operator complexes.
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Nucleic Acids Res,
38,
6286-6300.
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P.N.Minh,
N.Devroede,
J.Massant,
D.Maes,
and
D.Charlier
(2009).
Insights into the architecture and stoichiometry of Escherichia coli PepA*DNA complexes involved in transcriptional control and site-specific DNA recombination by atomic force microscopy.
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Nucleic Acids Res,
37,
1463-1476.
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Y.W.Tan,
J.A.Hanson,
and
H.Yang
(2009).
Direct Mg2+ Binding Activates Adenylate Kinase from Escherichia coli.
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J Biol Chem,
284,
3306-3313.
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D.Shi,
V.Sagar,
Z.Jin,
X.Yu,
L.Caldovic,
H.Morizono,
N.M.Allewell,
and
M.Tuchman
(2008).
The crystal structure of N-acetyl-L-glutamate synthase from Neisseria gonorrhoeae provides insights into mechanisms of catalysis and regulation.
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J Biol Chem,
283,
7176-7184.
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PDB codes:
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P.Meyer,
C.Evrin,
P.Briozzo,
N.Joly,
O.Bârzu,
and
A.M.Gilles
(2008).
Structural and Functional Characterization of Escherichia coli UMP Kinase in Complex with Its Allosteric Regulator GTP.
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J Biol Chem,
283,
36011-36018.
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PDB code:
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S.Pakhomova,
S.G.Bartlett,
A.Augustus,
T.Kuzuyama,
and
M.E.Newcomer
(2008).
Crystal Structure of Fosfomycin Resistance Kinase FomA from Streptomyces wedmorensis.
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J Biol Chem,
283,
28518-28526.
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PDB codes:
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C.Evrin,
M.Straut,
N.Slavova-Azmanova,
N.Bucurenci,
A.Onu,
L.Assairi,
M.Ionescu,
N.Palibroda,
O.Bârzu,
and
A.M.Gilles
(2007).
Regulatory mechanisms differ in UMP kinases from gram-negative and gram-positive bacteria.
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J Biol Chem,
282,
7242-7253.
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J.L.Tu,
K.H.Chin,
A.H.Wang,
and
S.H.Chou
(2007).
The crystallization of apo-form UMP kinase from Xanthomonas campestris is significantly improved in a strong magnetic field.
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Acta Crystallogr Sect F Struct Biol Cryst Commun,
63,
438-442.
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S.E.Lee,
S.Y.Kim,
C.M.Kim,
M.K.Kim,
Y.R.Kim,
K.Jeong,
H.J.Ryu,
Y.S.Lee,
S.S.Chung,
H.E.Choy,
and
J.H.Rhee
(2007).
The pyrH gene of Vibrio vulnificus is an essential in vivo survival factor.
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Infect Immun,
75,
2795-2801.
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B.Dhaliwal,
J.Ren,
M.Lockyer,
I.Charles,
A.R.Hawkins,
and
D.K.Stammers
(2006).
Structure of Staphylococcus aureus cytidine monophosphate kinase in complex with cytidine 5'-monophosphate.
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Acta Crystallogr Sect F Struct Biol Cryst Commun,
62,
710-715.
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PDB code:
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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
