Molecular dynamics simulations of the detoxification of paraoxon catalyzed by phosphotriesterase

Molecular dynamics simulations of the detoxification of paraoxon catalyzed by phosphotriesterase

Combined QM(PM3)/MM molecular dynamics simulations together with QM(DFT)/MM optimizations for key configurations have been performed to elucidate the enzymatic catalysis mechanism on the detoxification of paraoxon by phosphotriesterase (PTE). In the simulations, the PM3 parameters for the phosphorou...

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Published in:Journal of computational chemistry Vol. 30; no. 15; pp. 2388 - 2401
Main Authors: Zhang, Xin, Wu, Ruibo, Song, Lingchun, Lin, Yuchun, Lin, Menghai, Cao, Zexing, Wu, Wei, Mo, Yirong
Format: Journal Article
Language:English
Published: Hoboken Wiley Subscription Services, Inc., A Wiley Company 30-11-2009
Wiley Subscription Services, Inc
Subjects:
Analytical chemistry
Catalysis
Chemical reactions
combined QM/MM
Computer Simulation
detoxification
Hydrolysis
Models, Chemical
Molecular chemistry
molecular dynamics simulation
Molecular structure
Molecules
paraoxon
Paraoxon - chemistry
Phosphoric Triester Hydrolases - chemistry
Phosphoric Triester Hydrolases - metabolism
phosphotriesterase
Simulation
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Summary:Combined QM(PM3)/MM molecular dynamics simulations together with QM(DFT)/MM optimizations for key configurations have been performed to elucidate the enzymatic catalysis mechanism on the detoxification of paraoxon by phosphotriesterase (PTE). In the simulations, the PM3 parameters for the phosphorous atom were reoptimized. The equilibrated configuration of the enzyme/substrate complex showed that paraoxon can strongly bind to the more solvent‐exposed metal ion Znβ, but the free energy profile along the binding path demonstrated that the binding is thermodynamically unfavorable. This explains why the crystal structures of PTE with substrate analogues often exhibit long distances between the phosphoral oxygen and Znβ. The subsequent SN2 reaction plays the key role in the whole process, but controversies exist over the identity of the nucleophilic species, which could be either a hydroxide ion terminally coordinated to Znα or the μ‐hydroxo bridge between the α‐ and β‐metals. Our simulations supported the latter and showed that the rate‐limiting step is the distortion of the bound paraoxon to approach the bridging hydroxide. After this preparation step, the bridging hydroxide ion attacks the phosphorous center and replaces the diethyl phosphate with a low barrier. Thus, a plausible way to engineer PTE with enhanced catalytic activity is to stabilize the deformed paraoxon. Conformational analyses indicate that Trp131 is the closest residue to the phosphoryl oxygen, and mutations to Arg or Gln or even Lys, which can shorten the hydrogen bond distance with the phosphoryl oxygen, could potentially lead to a mutant with enhanced activity for the detoxification of organophosphates. © 2009 Wiley Periodicals, Inc. J Comput Chem, 2009
Bibliography:ArticleID:JCC21238
The Keck Foundation
Faculty Research and Creative Activities Support Fund
istex:EFE7FD9A23AA4ED07B0263B13F9AB496922D025D
Western Michigan University
ark:/67375/WNG-1BDQP5RW-P
The National Institute of Health (NIH)
ObjectType-Article-1
SourceType-Scholarly Journals-1
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Present address: Department of Chemistry, Digital Technology Center and Supercomputing Institute University of Minnesota, Minneapolis, MN 55455
ISSN:0192-8651
1096-987X
DOI:10.1002/jcc.21238