Catalytic Soman Scavenging by the Y337A/F338A Acetylcholinesterase Mutant Assisted with Novel Site-Directed Aldoximes.

Exposure to the nerve agent soman is difficult to treat due to the rapid dealkylation of the soman-acetylcholinesterase (AChE) conjugate known as aging. Oxime antidotes commonly used to reactivate organophosphate inhibited AChE are ineffective against soman, while the efficacy of the recommended nerve agent bioscavenger butyrylcholinesterase is limited by strictly stoichiometric scavenging. To overcome this limitation, we tested ex vivo, in human blood, and in vivo, in soman exposed mice, the capacity of aging-resistant human AChE mutant Y337A/F338A in combination with oxime HI-6 to act as a catalytic bioscavenger of soman. HI-6 was previously shown in vitro to efficiently reactivate this mutant upon soman, as well as VX, cyclosarin, sarin, and paraoxon, inhibition. We here demonstrate that ex vivo, in whole human blood, 1 μM soman was detoxified within 30 min when supplemented with 0.5 μM Y337A/F338A AChE and 100 μM HI-6. This combination was further tested in vivo. Catalytic scavenging of soman in mice improved the therapeutic outcome and resulted in the delayed onset of toxicity symptoms. Furthermore, in a preliminary in vitro screen we identified an even more efficacious oxime than HI-6, in a series of 42 pyridinium aldoximes, and 5 imidazole 2-aldoxime N-propylpyridinium derivatives. One of the later imidazole aldoximes, RS-170B, was a 2-3-fold more effective reactivator of Y337A/F338A AChE than HI-6 due to the smaller imidazole ring, as indicated by computational molecular models, that affords a more productive angle of nucleophilic attack.

[1]  Zoran Radić,et al.  Imidazole Aldoximes Effective in Assisting Butyrylcholinesterase Catalysis of Organophosphate Detoxification , 2014, Journal of medicinal chemistry.

[2]  P. Masson,et al.  Progress in the development of enzyme-based nerve agent bioscavengers. , 2013, Chemico-biological interactions.

[3]  F. Worek,et al.  In vitro kinetics of nerve agent degradation by fresh frozen plasma (FFP) , 2013, Archives of Toxicology.

[4]  M. Zlatković,et al.  Fresh Frozen Plasma as a Successful Antidotal Supplement in Acute Organophosphate Poisoning , 2013, Arhiv za higijenu rada i toksikologiju.

[5]  P. Taylor,et al.  Centrally acting oximes in reactivation of tabun-phosphoramidated AChE. , 2013, Chemico-biological interactions.

[6]  P. Taylor,et al.  Catalytic detoxification of nerve agent and pesticide organophosphates by butyrylcholinesterase assisted with non-pyridinium oximes. , 2013, The Biochemical journal.

[7]  Dan S. Tawfik,et al.  Evolved stereoselective hydrolases for broad-spectrum G-type nerve agent detoxification. , 2012, Chemistry & biology.

[8]  T. Letzel,et al.  In vitro and in vivo efficacy of PEGylated diisopropyl fluorophosphatase (DFPase). , 2012, Drug testing and analysis.

[9]  P. Taylor,et al.  Oxime-assisted Acetylcholinesterase Catalytic Scavengers of Organophosphates That Resist Aging* , 2011, The Journal of Biological Chemistry.

[10]  Tatyana Belinskaya,et al.  In search of a catalytic bioscavenger for the prophylaxis of nerve agent toxicity. , 2010, Chemico-biological interactions.

[11]  K. Kuča,et al.  In vivo experimental approach to treatment against tabun poisoning , 2010, Journal of enzyme inhibition and medicinal chemistry.

[12]  P. Masson,et al.  Butyrylcholinesterase for protection from organophosphorus poisons: catalytic complexities and hysteretic behavior. , 2010, Archives of biochemistry and biophysics.

[13]  A. Shafferman,et al.  Aging-Resistant Organophosphate Bioscavenger Based on Polyethylene Glycol-Conjugated F338A Human Acetylcholinesterase , 2008, Molecular Pharmacology.

[14]  P. Taylor,et al.  Application of Recombinant DNA Methods for Production of Cholinesterases as Organophosphate Antidotes and Detectors , 2007, Arhiv za higijenu rada i toksikologiju.

[15]  Z. Kovarik,et al.  Structure-Activity Approach in the Reactivation of Tabun-Phosphorylated Human Acetylcholinesterase with Bispyridinium para-Aldoximes , 2007, Arhiv za higijenu rada i toksikologiju.

[16]  G. Amitai,et al.  Asymmetric fluorogenic organophosphates for the development of active organophosphate hydrolases with reversed stereoselectivity. , 2007, Toxicology.

[17]  P. Taylor,et al.  Mutation of acetylcholinesterase to enhance oxime-assisted catalytic turnover of methylphosphonates. , 2007, Toxicology.

[18]  L. Lumley,et al.  Stoichiometric and catalytic scavengers as protection against nerve agent toxicity: a mini review. , 2007, Toxicology.

[19]  Dan S. Tawfik,et al.  Enhanced stereoselective hydrolysis of toxic organophosphates by directly evolved variants of mammalian serum paraoxonase , 2006, The FEBS journal.

[20]  Dan S. Tawfik,et al.  Structure and evolution of the serum paraoxonase family of detoxifying and anti-atherosclerotic enzymes , 2004, Nature Structural &Molecular Biology.

[21]  P. Taylor,et al.  Mutant cholinesterases possessing enhanced capacity for reactivation of their phosphonylated conjugates. , 2004, Biochemistry.

[22]  P. Taylor,et al.  Acetylcholinesterase active centre and gorge conformations analysed by combinatorial mutations and enantiomeric phosphonates. , 2003, The Biochemical journal.

[23]  Z. Kovarik,et al.  Exploring the active sites of cholinesterases by inhibition with bambuterol and haloxon , 2003 .

[24]  A. Shafferman,et al.  Carbocation-Mediated Processes in Biocatalysts. Contribution of Aromatic Moieties , 1997 .

[25]  N. Ariel,et al.  Aging of phosphylated human acetylcholinesterase: catalytic processes mediated by aromatic and polar residues of the active centre. , 1996, The Biochemical journal.

[26]  N. Munro Toxicity of the Organophosphate Chemical Warfare Agents GA, GB, and VX: Implications for Public Protection. , 1994, Environmental health perspectives.

[27]  B. P. Doctor,et al.  Comparison of antidote protection against soman by pyridostigmine, HI-6 and acetylcholinesterase. , 1993, The Journal of pharmacology and experimental therapeutics.

[28]  J. Valdés,et al.  A comparison of cholinergic effects of HI-6 and pralidoxime-2-chloride (2-PAM) in soman poisoning. , 1991, Toxicology letters.

[29]  Y. Ashani,et al.  Butyrylcholinesterase and acetylcholinesterase prophylaxis against soman poisoning in mice. , 1991, Biochemical pharmacology.

[30]  H. Benschop,et al.  Nerve agent stereoisomers: analysis, isolation and toxicology , 1988 .

[31]  G. Bucht,et al.  Aging and reactivatability of plaice cholinesterase inhibited by soman and its stereoisomers. , 1984, Biochemical pharmacology.

[32]  G. Z. Wolring,et al.  Stereospecific reactivation by some Hagedorn-oximes of acetylcholinesterases from various species including man, inhibited by soman. , 1984, Biochemical pharmacology.

[33]  H. Benschop,et al.  Isolation, anticholinesterase properties, and acute toxicity in mice of the four stereoisomers of the nerve agent soman. , 1984, Toxicology and applied pharmacology.

[34]  B. Bošković The treatment of Soman poisoning and its perspectives. , 1981, Fundamental and applied toxicology : official journal of the Society of Toxicology.

[35]  K. Courtney,et al.  A new and rapid colorimetric determination of acetylcholinesterase activity. , 1961, Biochemical pharmacology.

[36]  Carrol S. Weil,et al.  Tables for Convenient Calculation of Median-Effective Dose (LD50 or ED50) and Instructions in their Use. , 1952 .

[37]  W. R. Thompson USE OF MOVING AVERAGES AND INTERPOLATION TO ESTIMATE MEDIAN-EFFECTIVE DOSE , 1947, Bacteriological reviews.