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PDBsum entry 2vq7
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Oxidoreductase
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PDB id
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2vq7
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References listed in PDB file
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Key reference
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Title
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Revealing the moonlighting role of NADP in the structure of a flavin-Containing monooxygenase.
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Authors
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A.Alfieri,
E.Malito,
R.Orru,
M.W.Fraaije,
A.Mattevi.
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Ref.
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Proc Natl Acad Sci U S A, 2008,
105,
6572-6577.
[DOI no: ]
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PubMed id
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Abstract
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Flavin-containing monooxygenases (FMOs) are, after cytochromes P450, the most
important monooxygenase system in humans and are involved in xenobiotics
metabolism and variability in drug response. The x-ray structure of a soluble
prokaryotic FMO from Methylophaga sp. strain SK1 has been solved at 2.6-A
resolution and is now the protein of known structure with the highest sequence
similarity to human FMOs. The structure possesses a two-domain architecture,
with both FAD and NADP(+) well defined by the electron density maps. Biochemical
analysis shows that the prokaryotic enzyme shares many functional properties
with mammalian FMOs, including substrate specificity and the ability to
stabilize the hydroperoxyflavin intermediate that is crucial in substrate
oxygenation. On the basis of their location in the structure, the nicotinamide
ring and the adjacent ribose of NADP(+) turn out to be an integral part of the
catalytic site being actively engaged in the stabilization of the oxygenating
intermediate. This feature suggests that NADP(H) has a moonlighting role, in
that it adopts two binding modes that allow it to function in both flavin
reduction and oxygen reactivity modulation, respectively. We hypothesize that a
relative domain rotation is needed to bring NADP(H) to these distinct positions
inside the active site. Localization of mutations in human FMO3 that are known
to cause trimethylaminuria (fish-odor syndrome) in the elucidated FMO structure
provides a structural explanation for their biological effects.
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Figure 3.
Overall crystal structure of mFMO. (A) Ribbon diagram of the
monomer. FAD-binding domain (residues 8–169 and 281–450) is
orange and NADP-binding domain (residues 170–280) is green.
FAD is shown as yellow sticks and NADP^+ as blue sticks. The
positions of the long interdomain loop (residues 44–80), the
hinge connecting the two domains, and the polypeptide stretch
corresponding to residues 407–415 are outlined. mFMO residues
corresponding to TMAU-causing mutations (17) and polymorphisms
in hFMO3 (in parentheses) are in red and blue sticks,
respectively. The position of a long insert in hFMO3 (residues
238–299; Fig. 1B) is also indicated. It is expected to occupy
a surface-exposed position away from the active site. (B) Ribbon
representation of the mFMO dimer. One monomer is shown in the
same orientation and color as Fig. 3A; the other one is colored
gray, with the NADP-binding domain in darker gray.
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Figure 5.
The role of NADP^+ in the stabilization of
C4a-hydroperoxyflavin intermediate. (A) Modeling experiment in
which the hypothetical structure of C4a-hydroperoxyflavin was
superimposed to the flavin in mFMO structure. The color code is
the same as in Fig. 4B. Hypothetical hydrogen bonds involving
the hydroperoxyflavin atoms are shown as blue dashed lines. The
accommodation of the additional oxygen atoms of the C4a-adduct
would require a shift of ≈1.5 Å of Asn-78 side chain
(whose conformation in the native structure is shown as thin
black stick). (B) Comparison of the NADP^+-binding mode in S.
pombe (Protein Data Bank ID code 2gv8) and Methylophaga FMOs.
The picture was obtained by superimposing the Cα atoms of the
two proteins and shows the FAD (yellow) and NADP^+ (blue)
molecules of mFMO together with FAD and NADP^+ of the S. pombe
enzyme (red). The N5 and C4a atoms of the flavin and C4 and C2
atoms of NADP^+ are labeled.
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