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PDBsum entry 5u3f
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References listed in PDB file
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Key reference
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Title
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Mechanism-Based inhibition of the mycobacterium tuberculosis branched-Chain aminotransferase by d- And l-Cycloserine.
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Authors
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T.M.Amorim franco,
L.Favrot,
O.Vergnolle,
J.S.Blanchard.
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Ref.
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ACS Chem Biol, 2017,
12,
1235-1244.
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PubMed id
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Abstract
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The branched-chain aminotransferase is a pyridoxal 5'-phosphate (PLP)-dependent
enzyme responsible for the final step in the biosynthesis of all three
branched-chain amino acids, l-leucine, l-isoleucine, and l-valine, in bacteria.
We have investigated the mechanism of inactivation of the branched-chain
aminotransferase from Mycobacterium tuberculosis (MtIlvE) by d- and
l-cycloserine. d-Cycloserine is currently used only in the treatment of
multidrug-drug-resistant tuberculosis. Our results show a time- and
concentration-dependent inactivation of MtIlvE by both isomers, with
l-cycloserine being a 40-fold better inhibitor of the enzyme. Minimum inhibitory
concentration (MIC) studies revealed that l-cycloserine is a 10-fold better
inhibitor of Mycobacterium tuberculosis growth than d-cycloserine. In addition,
we have crystallized the MtIlvE-d-cycloserine inhibited enzyme, determining the
structure to 1.7 Å. The structure of the covalent d-cycloserine-PMP adduct
bound to MtIlvE reveals that the d-cycloserine ring is planar and aromatic, as
previously observed for other enzyme systems. Mass spectrometry reveals that
both the d-cycloserine- and l-cycloserine-PMP complexes have the same mass, and
are likely to be the same aromatized, isoxazole product. However, the kinetics
of formation of the MtIlvE d-cycloserine-PMP and MtIlvE l-cycloserine-PMP
adducts are quite different. While the kinetics of the formation of the MtIlvE
d-cycloserine-PMP complex can be fit to a single exponential, the formation of
the MtIlvE l-cycloserine-PMP complex occurs in two steps. We propose a chemical
mechanism for the inactivation of d- and l-cycloserine which suggests a
stereochemically determined structural role for the differing kinetics of
inactivation. These results demonstrate that the mechanism of action of
d-cycloserine's activity against M. tuberculosis may be more complicated than
previously thought and that d-cycloserine may compromise the in vivo activity of
multiple PLP-dependent enzymes, including MtIlvE.
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