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X-ray crystallographic snapshots of reaction intermediates in the G117H mutant of human butyrylcholinesterase, a nerve agent target engineered into a catalytic bioscavenger.

Nachon F, Carletti E, Wandhammer M, Nicolet Y, Schopfer LM, Masson P, Lockridge O
Biochem J 434 73-82 (2011)
Related entries: 2xmb, 2xmc, 2xmg

Cited: 19 times
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Abstract

OPs (organophosphylates) exert their acute toxicity through inhibition of acetylcholinesterase, by phosphylation of the catalytic serine residue. Engineering of human butyrylcholinesterase, by substitution of a histidine residue for the glycine residue at position 117, led to the creation of OP hydrolase activity. However, the lack of structural information and poor understanding of the hydrolytic mechanism of the G117H mutant has hampered further improvements in the catalytic activity. We have solved the crystallographic structure of the G117H mutant with a variety of ligands in its active site. A sulfate anion bound to the active site suggested the positioning for an OP prior to phosphylation. A fluoride anion was found in the active site when NaF was added to the crystallization buffer. In the fluoride complex, the imidazole ring from the His117 residue was substantially shifted, adopting a relaxed conformation probably close to that of the unliganded mutant enzyme. Additional X-ray structures were obtained from the transient covalent adducts formed upon reaction of the G117H mutant with the OPs echothiophate and VX [ethyl ({2-[bis(propan-2-yl)amino]ethyl}sulfanyl](methyl)phosphinate]. The position of the His117 residue shifted in response to the introduction of these adducts, overlaying the phosphylserine residue. These structural data suggest that the dephosphylation mechanism involves either a substantial conformational change of the His117 residue or an adjacent nucleophilic substitution by water.

Articles - 2xmd mentioned but not cited (3)

  1. Optimization of Cholinesterase-Based Catalytic Bioscavengers Against Organophosphorus Agents. Lushchekina SV, Schopfer LM, Grigorenko BL, Nemukhin AV, Varfolomeev SD, Lockridge O, Masson P. Front Pharmacol 9 211 (2018)
  2. Steady-State Kinetics of Enzyme-Catalyzed Hydrolysis of Echothiophate, a P-S Bonded Organophosphorus as Monitored by Spectrofluorimetry. Zueva IV, Lushchekina SV, Daudé D, Chabrière E, Masson P. Molecules 25 E1371 (2020)
  3. The Preferable Binding Pose of Canonical Butyrylcholinesterase Substrates Is Unproductive for Echothiophate. Zlobin AS, Zalevsky AO, Mokrushina YA, Kartseva OV, Golovin AV, Smirnov IV. Acta Naturae 10 121-124 (2018)


Reviews citing this publication (6)

  1. Highlights on contemporary recognition and sensing of fluoride anion in solution and in the solid state. Cametti M, Rissanen K. Chem Soc Rev 42 2016-2038 (2013)
  2. Progress in the development of enzyme-based nerve agent bioscavengers. Nachon F, Brazzolotto X, Trovaslet M, Masson P. Chem Biol Interact 206 536-544 (2013)
  3. Cholinesterase reactivators and bioscavengers for pre- and post-exposure treatments of organophosphorus poisoning. Masson P, Nachon F. J Neurochem 142 Suppl 2 26-40 (2017)
  4. New insights on molecular interactions of organophosphorus pesticides with esterases. Mangas I, Estevez J, Vilanova E, França TC. Toxicology 376 30-43 (2017)
  5. A Comprehensive Review of Cholinesterase Modeling and Simulation. De Boer D, Nguyen N, Mao J, Moore J, Sorin EJ. Biomolecules 11 580 (2021)
  6. Emergence of catalytic bioscavengers against organophosphorus agents. Masson P, Lushchekina SV. Chem Biol Interact 259 319-326 (2016)

Articles citing this publication (10)

  1. JLigand: a graphical tool for the CCP4 template-restraint library. Lebedev AA, Young P, Isupov MN, Moroz OV, Vagin AA, Murshudov GN. Acta Crystallogr D Biol Crystallogr 68 431-440 (2012)
  2. How the Same Core Catalytic Machinery Catalyzes 17 Different Reactions: the Serine-Histidine-Aspartate Catalytic Triad of α/β-Hydrolase Fold Enzymes. Rauwerdink A, Kazlauskas RJ. ACS Catal 5 6153-6176 (2015)
  3. Comparison of the Binding of Reversible Inhibitors to Human Butyrylcholinesterase and Acetylcholinesterase: A Crystallographic, Kinetic and Calorimetric Study. Rosenberry TL, Brazzolotto X, Macdonald IR, Wandhammer M, Trovaslet-Leroy M, Darvesh S, Nachon F. Molecules 22 E2098 (2017)
  4. Human butyrylcholinesterase produced in insect cells: huprine-based affinity purification and crystal structure. Brazzolotto X, Wandhammer M, Ronco C, Ronco C, Trovaslet M, Jean L, Lockridge O, Renard PY, Nachon F. FEBS J 279 2905-2916 (2012)
  5. Structural study of the complex stereoselectivity of human butyrylcholinesterase for the neurotoxic V-agents. Wandhammer M, Carletti E, Van der Schans M, Gillon E, Nicolet Y, Masson P, Goeldner M, Noort D, Nachon F. J Biol Chem 286 16783-16789 (2011)
  6. Why does the G117H mutation considerably improve the activity of human butyrylcholinesterase against sarin? Insights from quantum mechanical/molecular mechanical free energy calculations. Yao Y, Liu J, Zhan CG. Biochemistry 51 8980-8992 (2012)
  7. Characterization of butyrylcholinesterase in bovine serum. Dafferner AJ, Lushchekina S, Masson P, Xiao G, Schopfer LM, Lockridge O. Chem Biol Interact 266 17-27 (2017)
  8. Understanding the non-catalytic behavior of human butyrylcholinesterase silent variants: Comparison of wild-type enzyme, catalytically active Ala328Cys mutant, and silent Ala328Asp variant. Lushchekina S, Nemukhin A, Varfolomeev S, Masson P. Chem Biol Interact 259 223-232 (2016)
  9. Development of organophosphate hydrolase activity in a bacterial homolog of human cholinesterase. Legler PM, Boisvert SM, Compton JR, Millard CB. Front Chem 2 46 (2014)
  10. Rapid Mechanistic Evaluation and Parameter Estimation of Putative Inhibitors in a Single-Step Progress-Curve Analysis: The Case of Horse Butyrylcholinesterase. Stojan J. Molecules 22 E1248 (2017)


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