Unveiling SalL Chlorinase Reaction Mechanism and Selectivity through Quantum Mechanical/Molecular Mechanics and Activation‐Strain Model

Chlorinase (SalL) is an enzyme involved in the biosynthesis pathway of Salinosporamide A. Here, the reaction mechanism of SAM chlorination and fluorination in SalL using QM/MM calculations is studied. The analysis indicates that the configuration of interaction between the halide and the halogen pocket contributes to the reduced barrier height, favoring the charge transfer process during the reaction.

Here, an exhaustive exploration of the reaction mechanism toward the chlorination process carried out by SalL, a chlorinase enzyme that catalyzes the conversion of SAM into 5′-chloro-5′-deoxyadenosine through an S _N 2 reaction, is presented. To this end, molecular dynamics simulations and quantum mechanical/molecular mechanics calculations are performed, and 14 density functionals are benchmarked. Among the tested functionals, TPSSh(BJ) provides the closest energy barrier to experimental value. Three configurations of interaction between chloride and the halogen pocket are found, where the best model exhibits a barrier height of 20.1 kcal mol⁻¹, close to the 19.9 kcal mol⁻¹ experimentally obtained. This model is characterized by the chloride interacting with the backbone-amide of Gly131 and Tyr130. The reaction pathway is calculated through the intrinsic reaction coordinate approach, and it is characterized using reaction force analysis and the activation-strain model with energy decomposition analysis to obtain chemical insights into the inner working of this enzyme. According to the main findings, the overstabilization of the halogen binding on the active site increases the barrier height, explaining the lack of activity against fluoride, while the interaction energy between nucleophile−electrophile is responsible of reducing the barrier height, with the orbital interaction energy as the main stabilizing factor during the chlorination process.

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