Oxygen-Free Regioselective Biocatalytic Demethylation of Methyl-phenyl Ethers via Methyltransfer Employing Veratrol-<i>O</i>-demethylase

Grimm, Christopher; Lazzarotto, Mattia; Pompei, Simona; Schichler, Johanna; Richter, Nina; Farnberger, Judith E.; Fuchs, Michael; Kroutil, Wolfgang

doi:10.1021/acscatal.0c02790

Cited by 23 publications

(27 citation statements)

References 63 publications

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“…This finding shows how first and second sphere interactions in a protein scaffold can play a significant role in directing the utility of different proteins for non-native catalysis. Combined with our previous report of non-native styrene alkylation using CarH* 14 and studies exploring the substrate scope of B12-depenent methyl transferases, 22,23 this study highlights the utility of corrinoid proteins for biocatalysis and how structure-based homology searches can be used to identify enzymes for this purpose.…”

Section: Discussionsupporting

confidence: 62%

First and Second Sphere Interactions Accelerate Non-Native N-Alkylation Catalysis by the Thermostable, Methanol-Tolerant B12-Dependent Enzyme MtaC

Kumar

Yang

et al. 2022

Preprint

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During efforts to explore the range of reactions catalyzed by the previously-engineered B12-dependent enzyme CarH*, we found that this enzyme catalyzes N-alkylation of aniline using ethyl diazoacetate but that B12 itself provides only trace conversion for this reaction. This observation suggested that the unique primary and second coordination sphere provided by CarH* accelerates non-native N-alkylation catalysis and that other B12-dependent proteins could provide further improvements in activity. We used a structural homology search to identify the corrinoid protein MtaC, which was reconstituted with B12 to generate a catalyst with significantly-improved aniline N-alkylation activity on a range of substrates. MtaC also displays remarkable thermal stability and organic solvent tolerance, remaining folded even in pure methanol. These results highlight how protein scaffolds can be used to impart new activity and other beneficial properties to metal catalysts and suggest that MtaC could serve as a useful platform for non-native B12 catalysis.

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Section: Discussionsupporting

confidence: 62%

First and Second Sphere Interactions Accelerate Non-Native N-Alkylation Catalysis by the Thermostable, Methanol-Tolerant B12-Dependent Enzyme MtaC

Kumar

Yang

et al. 2022

Preprint

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“…B12-dependent enzymes are underutilized in biocatalysis relative to other metalloenzymes. Recent examples exploring the substrate scope of native B12-dependent enzyme catalysis 4,34 and the broad range of reactions catalyzed by B12 cofactors 7 suggest that suitable systems could find broader application in biocatalysis. This study establishes that a B12-dependent enzyme can catalyze a transformation distinct from its native reaction.…”

Section: Discussionmentioning

confidence: 99%

Controlling Non-Native B12 Reactivity and Catalysis in the Transcription Factor CarH

Yang

Gerroll

Jiang

et al. 2021

Preprint

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Vitamin B12 derivatives catalyze a wide range of organic transformations, but B12-dependent enzymes are underutilized in biocatalysis relative to other metalloenzymes. In this study, we engineered a variant of the transcription factor CarH, called CarH*, that catalyzes styrene C-H alkylation with improved yield and selectivity relative to B12 itself. While the native function of CarH involves transcription regulation via AdoCbl Co(III)-carbon bond cleavage and β-hydride elimination to generate 4’,5’-didehydroadenosine, CarH*-catalyzed styrene alkylation proceeds via non-native oxidative addition and olefin addition coupled with a native-like β-hydride elimination. Mechanistic studies on this reaction echo findings from earlier studies on AdoCbl homolysis under strong cage conditions to suggest that CarH* can enable non-native radical chemistry with improved selectivity relative to B12 itself. These findings lay the groundwork for the development of B12-dependent enzymes as catalysts for a wide range of non-native transformations.

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“…The one pot protocol was shown to be applicable for a broad scope of substituted guaiacol derivatives, whereby many of them were transformed with a conversion exceeding 90 %, at 30 °C and mild pH (pH 6.5) in buffer. Furthermore, the approach should be extendable to other cobalamin dependent methyltransferases possessing different preference for the substrate pattern [27] . We envisage that the substrate scope could be broadened by enzyme engineering.…”

Section: Methodsmentioning

confidence: 99%

Thiols Act as Methyl Traps in the Biocatalytic Demethylation of Guaiacol Derivatives

et al. 2021

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Demethylating methyl phenyl ethers is challenging, especially when the products are catechol derivatives prone to follow-up reactions. For biocatalytic demethylation, monooxygenases have previously been described requiring molecular oxygen which may cause oxidative side reactions. Here we show that such compounds can be demethylated anaerobically by using cobalamin-dependent methyltransferases exploiting thiols like ethyl 3-mercaptopropionate as a methyl trap. Using just two equivalents of this reagent, a broad spectrum of substituted guaiacol derivatives were demethylated, with conversions mostly above 90 %. This strategy was used to prepare the highly valuable antioxidant hydroxytyrosol on a one-gram scale in 97 % isolated yield.

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Oxygen-Free Regioselective Biocatalytic Demethylation of Methyl-phenyl Ethers via Methyltransfer Employing Veratrol-O-demethylase

Cited by 23 publications

References 63 publications

First and Second Sphere Interactions Accelerate Non-Native N-Alkylation Catalysis by the Thermostable, Methanol-Tolerant B12-Dependent Enzyme MtaC

First and Second Sphere Interactions Accelerate Non-Native N-Alkylation Catalysis by the Thermostable, Methanol-Tolerant B12-Dependent Enzyme MtaC

Controlling Non-Native B12 Reactivity and Catalysis in the Transcription Factor CarH

Thiols Act as Methyl Traps in the Biocatalytic Demethylation of Guaiacol Derivatives

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