Δ-FeOOH as Support for Immobilization Peroxidase: Optimization via a Chemometric Approach.

Owing to their high surface area, stability, and functional groups on the surface, iron oxide hydroxide nanoparticles have attracted attention as enzymatic support. In this work, a chemometric approach was performed, aiming at the optimization of the horseradish peroxidase (HRP) immobilization process on Δ-FeOOH nanoparticles (NPs). The enzyme/NPs ratio (X1), pH (X2), temperature (X3), and time (X4) were the independent variables analyzed, and immobilized enzyme activity was the response variable (Y). The effects of the factors were studied using a factorial design at two levels (-1 and 1). The biocatalyst obtained was evaluated for the ferulic acid (FA) removal, a pollutant model. The materials were characterized by X-ray powder diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), and scanning electron microscopy (SEM). The SEM images indicated changes in material morphology. The independent variables X1 (-0.57), X2 (0.71), and X4 (0.42) presented the significance effects estimate. The variable combinations resulted in two significance effects estimates, X1*X2 (-0.57) and X2*X4 (0.39). The immobilized HRP by optimized conditions (X1 = 1/63 (enzyme/NPs ratio, X2 = pH 8, X4 = 60 °C, and 30 min) showed high efficiency for FA oxidation (82%).

Molecular Docking, Metal Substitution and Hydrolysis Reaction of Chiral Substrates of Phosphotriesterase.

During World War II, organophosphorus compounds with neurotoxic action were developed and used as the basis for the development of structures currently used as pesticides in the agricultural industry. Among the nerve agents, Tabun, Sarin, Soman and VX are the most important. The factor responsible for the high toxicity of organophosphorus (OP) is the acetylcholinesterase inhibition. However, one of the characterized enzymes capable of degrading OP is Phosphotriesterase (PTE). This enzyme has generated considerable interest for applications of rapid and complete detoxification. Due to the importance of bioremediation methods for the poisoning caused by OP, this work aims to study the interaction mode between the PTE enzyme and organophosphorus compounds, in this case, Sarin, Soman, Tabun and VX have been used, which are potent acetylcholinesterase inhibitors, taking into account the enantiomers "Rp" and " Sp" of each compound, with the Sp-enantiomers presenting the higher toxicity. With that, we were able to demonstrate the existence of the stereochemical preference by PTE in these compounds. With the purpose of increasing the speed of the hydrolysis mechanism, we have proposed a modification in the enzyme active site structure, where Zn(2+) ions were substituted by Al(3+) ions. To analyze the stability of Al(3+) ions in the wild-type PTE active site, MD simulations were also performed. This mutation brought relevant results; in this case, there was a reduction of the reaction energy barrier for all the compounds, mainly for VX in which the reaction presented lower activation energy values, and consequently, a faster hydrolysis process.