Combined Experimental and Theoretical Study on the Reactivity of Compounds I and II in Horseradish Peroxidase Biomimetics

For the exploration of the intrinsic reactivity of two key active species in the catalytic cycle of horseradish peroxidase (HRP), Compound I (HRP‐I) and Compound II (HRP‐II), we generated in situ [Fe IV O(TMP +. )(2‐MeIm)] + and [Fe IV O(TMP)(2‐MeIm)] 0 (TMP=5,10,15,20‐tetramesitylporphyrin; 2‐MeIm=2‐methylimidazole) as biomimetics for HRP‐I and HRP‐II, respectively. Their catalytic activities in epoxidation, hydrogen abstraction, and heteroatom oxidation reactions were studied in acetonitrile at −15 °C by utilizing rapid‐scan UV/Vis spectroscopy. Comparison of the second‐order rate constants measured for the direct reactions of the HRP‐I and HRP‐II mimics with the selected substrates clearly confirmed the outstanding oxidizing capability of the HRP‐I mimic, which is significantly higher than that of HRP‐II. The experimental study was supported by computational modeling (DFT calculations) of the oxidation mechanism of the selected substrates with the involvement of quartet and doublet HRP‐I mimics ( 2,4 Cpd I) and the closed‐shell triplet spin HRP‐II model ( 3 Cpd II) as oxidizing species. The significantly lower activation barriers calculated for the oxidation systems involving 2,4 Cpd I than those found for 3 Cpd II are in line with the much higher oxidizing efficiency of the HRP‐I mimic proven in the experimental part of the study. In addition, the DFT calculations show that all three reaction types catalyzed by HRP‐I occur on the doublet spin surface in an effectively concerted manner, whereas these reactions may proceed in a stepwise mechanism with the HRP‐II mimic as oxidant. However, the high desaturation or oxygen rebound barriers during CH bond activation processes by the HRP‐II mimic predict a sufficient lifetime for the substrate radical formed through hydrogen abstraction. Thus, the theoretical calculations suggest that the dissociation of the substrate radical may be a more favorable pathway than desaturation or oxygen rebound processes. Importantly, depending on the electronic nature of the oxidizing species, that is, 2,4 Cpd I or 3 Cpd II, an interesting region‐selective conversion phenomenon between sulfoxidation and H‐atom abstraction was revealed in the course of the oxidation reaction of dimethylsulfide. The combined experimental and theoretical study on the elucidation of the intrinsic reactivity patterns of the HRP‐I and HRP‐II mimics provides a valuable tool for evaluating the particular role of the HRP active species in biological systems.