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PDBsum entry 4lcm
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References listed in PDB file
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Key reference
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Title
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The role of distant mutations and allosteric regulation on lovd active site dynamics.
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Authors
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G.Jiménez-Osés,
S.Osuna,
X.Gao,
M.R.Sawaya,
L.Gilson,
S.J.Collier,
G.W.Huisman,
T.O.Yeates,
Y.Tang,
K.N.Houk.
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Ref.
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Nat Chem Biol, 2014,
10,
431-436.
[DOI no: ]
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PubMed id
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Abstract
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Natural enzymes have evolved to perform their cellular functions under complex
selective pressures, which often require their catalytic activities to be
regulated by other proteins. We contrasted a natural enzyme, LovD, which acts on
a protein-bound (LovF) acyl substrate, with a laboratory-generated variant that
was transformed by directed evolution to accept instead a small free acyl
thioester and no longer requires the acyl carrier protein. The resulting
29-mutant variant is 1,000-fold more efficient in the synthesis of the drug
simvastatin than the wild-type LovD. This is to our knowledge the first
nonpatent report of the enzyme currently used for the manufacture of simvastatin
as well as the intermediate evolved variants. Crystal structures and
microsecond-scale molecular dynamics simulations revealed the mechanism by which
the laboratory-generated mutations free LovD from dependence on protein-protein
interactions. Mutations markedly altered conformational dynamics of the
catalytic residues, obviating the need for allosteric modulation by the acyl
carrier LovF.
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