Yiping Jiang scite author profile

Understanding the molecular basis for controlled H 2 O 2 activation is of fundamental importance for peroxide-driven catalysis by metalloenzymes. In addition to O 2 activation in the presence of stoichiometric reductants, an increasing number of metalloenzymes are found to activate the H 2 O 2 cosubstrate for oxidative transformations in the absence of stoichiometric reductants. Herein, we characterized the X-ray structure of the P450BM3 F87A mutant in complex with the dual-functional small molecule (DFSM) N-(ω-imidazolyl)-hexanoyl-Lphenylalanine (Im-C6-Phe), which enables an efficient peroxygenase activity for P450BM3. Our computational investigations show that the H 2 O 2 activations by P450BM3 are highly dependent on the substrate and the DFSM. In the absence of both the substrate and the DFSM, H 2 O 2 activation via the O−O homolysis mechanism is significantly inhibited by the H-bonding network from the proximal H of H 2 O 2 . However, the presence of the substrate expels the solvation waters and disrupts the H-bonding network from the proximal H of H 2 O 2 , thus remarkably favoring homolytic O−O cleavage toward Cpd I formation. However, the presence of the DFSM forms a proton channel between the imidazolyl group of the DFSM and the proximal H of H 2 O 2 , thus enabling a heterolytic O−O cleavage and Cpd I formation that is greatly favored over the homolysis mechanism. Meanwhile, our simulations demonstrate that the H-bonding network from the distal H of H 2 O 2 is the key to control of the H 2 O 2 activation in the homolytic route. These findings are in line with all available experimental data and highlight the key roles of H-bonding networks in dictating H 2 O 2 activations.

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Resonance tunneling through photonic quantum wells

Jiang

Niu

Lin

1999

Phys. Rev. B

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Enabling Peroxygenase Activity in Cytochrome P450 Monooxygenases by Engineering Hydrogen Peroxide Tunnels

et al. 2023

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Given prominent physicochemical similarities between H2O2 and water, we report a new strategy for promoting the peroxygenase activity of P450 enzymes by engineering their water tunnels to facilitate H2O2 access to the heme center buried therein. Specifically, the H2O2-driven activities of two native NADH-dependent P450 enzymes (CYP199A4 and CYP153A M.aq ) increase significantly (by >183-fold and >15-fold, respectively). Additionally, the amount of H2O2 required for an artificial P450 peroxygenase facilitated by a dual-functional small molecule to obtain the desired product is reduced by 95%–97.5% (with ∼95% coupling efficiency). Structural analysis suggests that mutating the residue at the bottleneck of the water tunnel may open a second pathway for H2O2 to flow to the heme center (in addition to the natural substrate tunnel). This study highlights a promising, generalizable strategy whereby P450 monooxygenases can be modified to adopt peroxygenase activity through H2O2 tunnel engineering, thus broadening the application scope of P450s in synthetic chemistry and synthetic biology.

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Yiping Jiang

H-Bonding Networks Dictate the Molecular Mechanism of H₂O₂ Activation by P450

Resonance tunneling through photonic quantum wells

Enabling Peroxygenase Activity in Cytochrome P450 Monooxygenases by Engineering Hydrogen Peroxide Tunnels

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Yiping Jiang

H-Bonding Networks Dictate the Molecular Mechanism of H2O2 Activation by P450

Resonance tunneling through photonic quantum wells

Enabling Peroxygenase Activity in Cytochrome P450 Monooxygenases by Engineering Hydrogen Peroxide Tunnels

Contact Info

Product

Resources

About

H-Bonding Networks Dictate the Molecular Mechanism of H₂O₂ Activation by P450