Enzymatic detoxification: a sustainable means of degrading toxic organophosphate pesticides and chemical warfare nerve agents

Manco, Giuseppe; Porzio, Elena; Suzumoto, Yoko

doi:10.1002/jctb.5603

Cited by 61 publications

(34 citation statements)

References 189 publications

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“…In this case, the metal ion in Pseudomonas diminuta and Sphingobium fuliginis strain ATCC 27551 PTE have Zn 2+, as the ion, whereas for the Geobacillus stearothermophilus PTE it is Co 2+ [7,30]. In the absence of a substrate, the α zinc metal was reported as buried near to His55, His 57, and Asp 301, and the β zinc metal was more exposed to the solvent [6,7,30]. The divalent metal ions in the active site center are reported to contribute to the activity and stability of the enzyme.…”

Section: Bacterial Phosphotriesterase 3d Structuresmentioning

confidence: 97%

“…The active site pocket of the PTE in a hydrophobic condition contains two metal ions (Zn 2+ Mn 2+ , Co 2+ , and Cd 2+ ) bridged with side-chains of histidine residues that are clustered around the metal atoms [22,27]. A number of the crystal structures of PTE isolated from bacteria such as Pseudomonas pseudoalcaligenes (2.1 Å), Pseudomonas diminuta (2.0 Å), Mycobacterium tuberculosis (2.27 Å), Agrobacterium radiobacter (1.99 Å), Geobacillus stearothermophilus (2.09 Å), and Geobacillus kaustophilus HTA426 (2.05 Å) have been determined [4,7,16,28,29]. In this review, three crystal structures of PTEs from Pseudomonas diminuta, Sphingobium fuliginis strain ATCC 27551, and Geobacillus stearothermophilus (PLL) are used as examples in this section to shown the similarities and differences in their 3D structure Figure 2.…”

Section: Bacterial Phosphotriesterase 3d Structuresmentioning

confidence: 99%

“…In addition, all PTEs require divalent metals to directly ligate the substrate to simplify the hydrolysis process Figure 2(B1-B3) [5,6]. In this case, the metal ion in Pseudomonas diminuta and Sphingobium fuliginis strain ATCC 27551 PTE have Zn 2+, as the ion, whereas for the Geobacillus stearothermophilus PTE it is Co 2+ [7,30]. In the absence of a substrate, the α zinc metal was reported as buried near to His55, His 57, and Asp 301, and the β zinc metal was more exposed to the solvent [6,7,30].…”

Section: Bacterial Phosphotriesterase 3d Structuresmentioning

confidence: 99%

“…Similarly, in thiophosphotriesters (methyl parathion) and phosphorothiolesters (malathion), the phosphate group is still in the center but the phosphoryl oxygen is replaced by sulfur and one or more of the ester oxygens are replaced by sulfur Figure 1B,C. To date these compounds are still widely used especially in agricultural industries [7]. Moreover, OPs compounds are easily drained into ground water that in turn will pollute water supplies and surrounding land areas [8].…”

Section: Introductionmentioning

confidence: 99%

“…Many alternative technologies have been studied and developed to resolve this problem, using various chemical, physical, and biological methods. Unfortunately, most of these methods are expensive and may not suitable or even safe for the decontamination of human beings [7]. They may be very harsh and may not be very specific [3].…”

Section: Introductionmentioning

confidence: 99%

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Microbial Phosphotriesterase: Structure, Function, and Biotechnological Applications

et al. 2019

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The role of phosphotriesterase as an enzyme which is able to hydrolyze organophosphate compounds cannot be disputed. Contamination by organophosphate (OP) compounds in the environment is alarming, and even more worrying is the toxicity of this compound, which affects the nervous system. Thus, it is important to find a safer way to detoxify, detect and recuperate from the toxicity effects of this compound. Phosphotriesterases (PTEs) are mostly isolated from soil bacteria and are classified as metalloenzymes or metal-dependent enzymes that contain bimetals at the active site. There are three separate pockets to accommodate the substrate into the active site of each PTE. This enzyme generally shows a high catalytic activity towards phosphotriesters. These microbial enzymes are robust and easy to manipulate. Currently, PTEs are widely studied for the detection, detoxification, and enzyme therapies for OP compound poisoning incidents. The discovery and understanding of PTEs would pave ways for greener approaches in biotechnological applications and to solve environmental issues relating to OP contamination.

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Section: Bacterial Phosphotriesterase 3d Structuresmentioning

confidence: 97%

Section: Bacterial Phosphotriesterase 3d Structuresmentioning

confidence: 99%

Section: Bacterial Phosphotriesterase 3d Structuresmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Microbial Phosphotriesterase: Structure, Function, and Biotechnological Applications

et al. 2019

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Engineering a Mesoporous Silicon Nanoparticle Cage to Enhance Performance of a Phosphotriesterase Enzyme for Degradation of VX Nerve Agent

Lu,

Moreno,

Huang

et al. 2024

Advanced Science

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The organophosphate (OP)‐hydrolyzing enzyme phosphotriesterase (PTE, variant L7ep‐3a) immobilized within a partially oxidized mesoporous silicon nanoparticle cage is synthesized and the catalytic performance of the enzyme@nanoparticle construct for hydrolysis of a simulant, dimethyl p‐nitrophenyl phosphate (DMNP), and the live nerve agent VX is benchmarked against the free enzyme. In a neutral aqueous buffer, the optimized construct shows a ≈2‐fold increase in the rate of DMNP turnover relative to the free enzyme. Enzyme@nanoparticles with more hydrophobic surface chemistry in the interior of the pores show lower catalytic activity, suggesting the importance of hydration of the pore interior on performance. The enzyme@nanoparticle construct is readily separated from the neutralized agent; the nanoparticle is found to retain DMNP hydrolysis activity through seven decontamination/recovery cycles. The nanoparticle cage stabilizes the enzyme against thermal denaturing and enzymatic (trypsin) degradation conditions relative to free enzyme. When incorporated into a topical gel formulation, the PTE‐loaded nanoparticles show high activity toward the nerve agent VX in an ex vivo rabbit skin model. In vitro acetylcholinesterase (AChE) assays in human blood show that the enzyme@nanoparticle construct decontaminates VX, preserving the biological function of AChE when exposed to an otherwise incapacitating dose.

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Screening for Improved Nerve Agent Simulants and Insights into Organophosphate Hydrolysis Reactions from DFT and QSAR Modeling

Mendonca

Snurr

2019

Chemistry A European J

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The effective detoxification of chemical warfare agents, specifically nerve agents, is a pressing issue in the modern world. Due to the high toxicity of these molecules, simulants are often used in experiments as substitutes for the agents. However, there is little reason to believe that the current simulants used in the literature are optimal predictors of nerve agent reactivity. Density functional theory calculations were performed on the alkaline hydrolysis of over 100 organophosphate molecules to identify improved simulants for the G‐series nerve agents soman and sarin, based on low toxicity and similarity to nerve agent hydrolysis energetics and degradation mechanism. This screening highlighted 5 molecules that have nearly identical reaction barriers to the actual agents, while being far less toxic. Quantitative structure–activity relationship (QSAR) models were also derived to determine the most significant molecular descriptors for describing the hydrolysis free energy barriers of these reactions. The optimal QSAR model was subjected to a thorough statistical analysis and validation procedure to confirm its predictive capacity, showing excellent quantitative and ranking accuracy. It was further shown that the model trained on G‐series agents can reliably predict energetics for other organophosphate classes as well, including VX. Through these computational insights, experimentalists may be aided in accurately and safely studying these reactions with less toxic simulants.

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Enzymatic detoxification: a sustainable means of degrading toxic organophosphate pesticides and chemical warfare nerve agents

Cited by 61 publications

References 189 publications

Microbial Phosphotriesterase: Structure, Function, and Biotechnological Applications

Microbial Phosphotriesterase: Structure, Function, and Biotechnological Applications

Engineering a Mesoporous Silicon Nanoparticle Cage to Enhance Performance of a Phosphotriesterase Enzyme for Degradation of VX Nerve Agent

Screening for Improved Nerve Agent Simulants and Insights into Organophosphate Hydrolysis Reactions from DFT and QSAR Modeling

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