Different Geometric Requirements for Cytochrome P450-Catalyzed Aliphatic Versus Aromatic Hydroxylation Results in Chemoselective Oxidation

Coleman, Tom; Kirk, Alicia M.; Lee, Joel H. Z.; Doherty, Daniel Z; Bruning, John B.; Krenske, Elizabeth H.; Voss, James J. De; Bell, Stephen

doi:10.1021/acscatal.1c05483

Cited by 21 publications

(48 citation statements)

References 47 publications

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“…The major metabolite was isolated by semi-prep HPLC and characterised by NMR spectroscopy (Figure S3). The NMR spectrum of the [13] 90 1.7 � 0.1 902 � 34…”

Section: Substrate Turnover and Product Distributionsmentioning

confidence: 99%

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Enabling Aromatic Hydroxylation in a Cytochrome P450 Monooxygenase Enzyme through Protein Engineering

Coleman

Lee

Kirk

et al. 2022

Chemistry A European J

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The cytochrome P450 (CYP) family of heme monooxygenases catalyse the selective oxidation of C−H bonds under ambient conditions. The CYP199A4 enzyme from Rhodopseudomonas palustris catalyses aliphatic oxidation of 4‐cyclohexylbenzoic acid but not the aromatic oxidation of 4‐phenylbenzoic acid, due to the distinct mechanisms of aliphatic and aromatic oxidation. The aromatic substrates 4‐benzyl‐, 4‐phenoxy‐ and 4‐benzoyl‐benzoic acid and methoxy‐substituted phenylbenzoic acids were assessed to see if they could achieve an orientation more amenable to aromatic oxidation. CYP199A4 could catalyse the efficient benzylic oxidation of 4‐benzylbenzoic acid. The methoxy‐substituted phenylbenzoic acids were oxidatively demethylated with low activity. However, no aromatic oxidation was observed with any of these substrates. Crystal structures of CYP199A4 with 4‐(3′‐methoxyphenyl)benzoic acid demonstrated that the substrate binding mode was like that of 4‐phenylbenzoic acid. 4‐Phenoxy‐ and 4‐benzoyl‐benzoic acid bound with the ether or ketone oxygen atom hydrogen‐bonded to the heme aqua ligand. We also investigated whether the substitution of phenylalanine residues in the active site could permit aromatic hydroxylation. Mutagenesis of the F298 residue to a valine did not significantly alter the substrate binding position or enable the aromatic oxidation of 4‐phenylbenzoic acid; however the F182L mutant was able to catalyse 4‐phenylbenzoic acid oxidation generating 2′‐hydroxy‐, 3′‐hydroxy‐ and 4′‐hydroxy metabolites in a 83 : 9 : 8 ratio, respectively. Molecular dynamics simulations, in which the distance and angle of attack were considered, demonstrated that in the F182L variant, in contrast to the wild‐type enzyme, the phenyl ring of 4‐phenylbenzoic acid attained a productive geometry for aromatic oxidation to occur.

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“…The major metabolite was isolated by semi-prep HPLC and characterised by NMR spectroscopy (Figure S3). The NMR spectrum of the [13] 90 1.7 � 0.1 902 � 34…”

Section: Substrate Turnover and Product Distributionsmentioning

confidence: 99%

“…-[e] 4-cyclohexylBA [13] � 95 0.45 � 0.05 169 � 11 52 � 6 33 � 2 4-tert-butylBA [12] � 95 39 � 2 227 � 4 227 � 32 100 � 13 4-methoxyBA [8c] � 95 0.28 � 0.01 1340 � 30 1220 � 120 91 � 10…”

Section: Substrate Turnover and Product Distributionsmentioning

confidence: 99%

Enabling Aromatic Hydroxylation in a Cytochrome P450 Monooxygenase Enzyme through Protein Engineering

Coleman

Lee

Kirk

et al. 2022

Chemistry A European J

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“…Over the years, many experimental and theoretical studies have been done to gain a clear mechanistic picture of biological aromatic oxidations. ,− In this regard, different mechanisms have been proposed for Cyt P450-mediated arene hydroxylation (Scheme ), such as (A) benzene oxide formation by the electrophilic attack of high-valent iron(IV)-oxo porphyrin π-cation radicals (Cpd I) on the aromatic ring, (B) electrophilic attack of Cpd I on the π-system to generate the radical/cationic σ-complexes, (C) electron transfer to Cpd I prior to the formation of σ-complexes, and (D) hydrogen atom abstraction by Cpd I from the aromatic ring and the subsequent rebound of the hydroxyl group. , Further, with the help of DFT studies, pathways C and D were ruled out, and a mechanism involving the formation of radical/cationic σ-complexes (pathway B) was found to be the most feasible. ,, In addition to this, in 2016, Fuji and co-workers demonstrated a kinetic study of aromatic oxidation (benzene, anisole, and naphthalene) using a series of Cpd I model complexes having different numbers of fluorine atoms in the meso-phenyl groups of the porphyrin ligand. On the basis of the Marcus plot obtained (slope = 0.60–0.68), a new mechanism (E) was proposed in which the electron transfer process between an aromatic compound and Cpd I is in equilibrium in a solvent cage and coupled with the subsequent bond formation …”

Section: Homogeneous Transition Metal Complexes In Benzene Hydroxylationmentioning

confidence: 99%

“… , Similarly, Fe(III) complexes of N3 ligands are also found to proceed via a hydroxyl radical mechanism, probably due to a less sterically constrained ligand environment to stabilize the iron–oxygen intermediate . With heme-iron complexes, a mechanism similar to Cyt P450 is proposed involving the formation of a high-valent iron-oxo with porphyrin π-cation radical species. − When it comes to non-heme systems, although complexes of both N4 and N5 ligands are found to form the common Fe III –OOH intermediate, the actual reactive species in both instances are understood to be different. In the case of iron complexes having N4 ligands, the high-valent iron(V)-oxo species is identified as the reactive species, especially in the presence of a carboxylic acid as a cocatalyst resulting from the heterolytic cleavage of the O–O bond in the Fe III –OOH intermediate. , In contrast, a caged pair, [Fe IV O + • OH] produced by the homolysis of O–O bond in Fe III –OOH species is the proposed intermediate in the case of iron complexes of N5 ligands. − Besides, with diiron complexes, the formation of oxido bridged reactive species are proposed in the catalytic mechanism. ,, Our overall mechanistic understanding of heme and non-heme-iron-mediated homogeneous benzene hydroxylation is illustrated in Scheme .…”

Section: Homogeneous Transition Metal Complexes In Benzene Hydroxylationmentioning

confidence: 99%

Rational Design of First-Row Transition Metal Complexes as the Catalysts for Oxidation of Arenes: A Homogeneous Approach

2022

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Researchers have always been intrigued by one-step selective hydroxylation of aromatic compounds since achieving adequate selectivity toward the target product and avoiding overoxidation are challenging. However, the naturally available oxygenase enzymes efficiently and selectively perform such transformations under normal atmospheric conditions. Inspired by naturally occurring oxygenase enzymes, researchers have undertaken numerous attempts to catalyze the oxidation of arenes using homogeneous and heterogeneous catalysts. In this regard, the first-row transition metal complexes are considered as candidates due to their abundance and redox characteristics. Therefore, this review focuses on catalyst design strategies to improve the efficiency and selectivity of arene oxidation and illustrates the distinctive homogeneous approaches reported in this area by employing first-row transition metal complexes.

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“…In fact, there are only a few native P450s belonging to the CYP152 family that are capable of efficiently using H 2 O 2 to perform their catalytic functions [ 20 , 21 , 22 ]. Considering the significant potential of peroxygenases as practical biocatalysts [ 23 , 24 , 25 , 26 ], many efforts have been made to develop a peroxide-driven P450 system [ 27 , 28 , 29 , 30 , 31 ].…”

Section: Introductionmentioning

confidence: 99%

Co-Crystal Structure-Guided Optimization of Dual-Functional Small Molecules for Improving the Peroxygenase Activity of Cytochrome P450BM3

Qin

Jiang

Chen

et al. 2022

IJMS

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We recently developed an artificial P450–H2O2 system assisted by dual-functional small molecules (DFSMs) to modify the P450BM3 monooxygenase into its peroxygenase mode, which could be widely used for the oxidation of non-native substrates. Aiming to further improve the DFSM-facilitated P450–H2O2 system, a series of novel DFSMs having various unnatural amino acid groups was designed and synthesized, based on the co-crystal structure of P450BM3 and a typical DFSM, N-(ω-imidazolyl)-hexanoyl-L-phenylalanine, in this study. The size and hydrophobicity of the amino acid residue in the DFSM drastically affected the catalytic activity (up to 5-fold), stereoselectivity, and regioselectivity of the epoxidation and hydroxylation reactions. Docking simulations illustrated that the differential catalytic ability among the DFSMs is closely related to the binding affinity and the distance between the catalytic group and heme iron. This study not only enriches the DFSM toolbox to provide more options for utilizing the peroxide-shunt pathway of cytochrome P450BM3, but also sheds light on the great potential of the DFSM-driven P450 peroxygenase system in catalytic applications based on DFSM tunability.

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Different Geometric Requirements for Cytochrome P450-Catalyzed Aliphatic Versus Aromatic Hydroxylation Results in Chemoselective Oxidation

Cited by 21 publications

References 47 publications

Enabling Aromatic Hydroxylation in a Cytochrome P450 Monooxygenase Enzyme through Protein Engineering

Enabling Aromatic Hydroxylation in a Cytochrome P450 Monooxygenase Enzyme through Protein Engineering

Rational Design of First-Row Transition Metal Complexes as the Catalysts for Oxidation of Arenes: A Homogeneous Approach

Co-Crystal Structure-Guided Optimization of Dual-Functional Small Molecules for Improving the Peroxygenase Activity of Cytochrome P450BM3

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