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PDBsum entry 6f05
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Contents |
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(+ 3 more)
204 a.a.
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193 a.a.
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References listed in PDB file
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Key reference
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Title
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Redox-Regulated methionine oxidation of arabidopsis thaliana glutathione transferase phi9 induces h-Site flexibility.
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Authors
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M.A.Tossounian,
K.Wahni,
I.Van molle,
D.Vertommen,
L.Astolfi rosado,
J.Messens.
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Ref.
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Protein Sci, 2019,
28,
56-67.
[DOI no: ]
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PubMed id
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Abstract
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Glutathione transferase enzymes help plants to cope with biotic and abiotic
stress. They mainly catalyze the conjugation of glutathione (GSH) onto
xenobiotics, and some act as glutathione peroxidase. With X-ray crystallography,
kinetics, and thermodynamics, we studied the impact of oxidation on Arabidopsis
thaliana glutathione transferase Phi 9 (GSTF9). GSTF9 has no cysteine in its
sequence, and it adopts a universal GST structural fold characterized by a
typical conserved GSH-binding site (G-site) and a hydrophobic
co-substrate-binding site (H-site). At elevated H2 O2
concentrations, methionine sulfur oxidation decreases its transferase activity.
This oxidation increases the flexibility of the H-site loop, which is reflected
in lower activities for hydrophobic substrates. Determination of the transition
state thermodynamic parameters shows that upon oxidation an increased enthalpic
penalty is counterbalanced by a more favorable entropic contribution. All in
all, to guarantee functionality under oxidative stress conditions, GSTF9 employs
a thermodynamic and structural compensatory mechanism and becomes substrate of
methionine sulfoxide reductases, making it a redox-regulated enzyme.
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