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PDBsum entry 2ez2
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References listed in PDB file
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Key reference
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Title
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Structures of apo- And holo-Tyrosine phenol-Lyase reveal a catalytically critical closed conformation and suggest a mechanism for activation by k+ ions.
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Authors
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D.Milić,
D.Matković-Calogović,
T.V.Demidkina,
V.V.Kulikova,
N.I.Sinitzina,
A.A.Antson.
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Ref.
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Biochemistry, 2006,
45,
7544-7552.
[DOI no: ]
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PubMed id
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Abstract
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Tyrosine phenol-lyase, a tetrameric pyridoxal 5'-phosphate dependent enzyme,
catalyzes the reversible hydrolytic cleavage of L-tyrosine to phenol and
ammonium pyruvate. Here we describe the crystal structure of the Citrobacter
freundii holoenzyme at 1.9 A resolution. The structure reveals a network of
protein interactions with the cofactor, pyridoxal 5'-phosphate, and details of
coordination of the catalytically important K+ ion. We also present the
structure of the apoenzyme at 1.85 A resolution. Both structures were determined
using crystals grown at pH 8.0, which is close to the pH of the maximal
enzymatic activity (8.2). Comparison of the apoenzyme structure with the one
previously determined at pH 6.0 reveals significant differences. The data
suggest that the decrease of the enzymatic activity at pH 6.0 may be caused by
conformational changes in the active site residues Tyr71, Tyr291, and Arg381 and
in the monovalent cation binding residue Glu69. Moreover, at pH 8.0 we observe
two different active site conformations: open, which was characterized before,
and closed, which is observed for the first time in beta-eliminating lyases. In
the closed conformation a significant part of the small domain undergoes an
extraordinary motion of up to 12 A toward the large domain, closing the active
site cleft and bringing the catalytically important Arg381 and Phe448 into the
active site. The closed conformation allows rationalization of the results of
previous mutational studies and suggests that the observed active site closure
is critical for the course of the enzymatic reaction and for the enzyme's
specificity toward its physiological substrate. Finally, the closed conformation
allows us to model keto(imino)quinonoid, the key transition intermediate.
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