Fluorinated<i>S</i>‐Adenosylmethionine as a Reagent for Enzyme‐Catalyzed Fluoromethylation

Peng, Jiaming; Liao, Cangsong; Bauer, Carsten; Seebeck, Florian P.

doi:10.1002/ange.202108802

Cited by 8 publications

(5 citation statements)

References 83 publications

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“…Several orthogonal and mutually beneficial developments have come from bottom-up approaches. [72] Versatile biocatalytic reaction platforms provide the experimentally rooted background for extending the scope of classical and new reaction classes, such as selective biocatalytic hydrolyses, [73] oxidations, [74] reductions, [75] glycosylations, [76] phosphorylations, [77] methylations and fluoromethylations, [78,79] addition [80] and elimination reactions, [81] and carboxylations. [82,83] The development of new-to-nature biocatalytic reactions [84] enables biocatalysis to enter completely new fields, such as sustainable silicon chemistry.…”

Section: Emerging Biocatalysis Research Areas Methodologies and Toolsmentioning

confidence: 99%

Biocatalysis as Key to Sustainable Industrial Chemistry

Alcántara

Marı́a²,

Littlechild

et al. 2022

ChemSusChem

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The role and power of biocatalysis in sustainable chemistry has been continuously brought forward step by step to its present outstanding position. The problem‐solving capabilities of biocatalysis have been realized by numerous substantial achievements in biology, chemistry and engineering. Advances and breakthroughs in the life sciences and interdisciplinary cooperation with chemistry have clearly accelerated the implementation of biocatalytic synthesis in modern chemistry. Resource‐efficient biocatalytic manufacturing processes have already provided numerous benefits to sustainable chemistry as well as customer‐centric value creation in the pharmaceutical, food, flavor, fragrance, vitamin, agrochemical, polymer, specialty, and fine chemical industries. Biocatalysis can make significant contributions not only to manufacturing processes, but also to the design of completely new value‐creation chains. Biocatalysis can now be considered as a key enabling technology to implement sustainable chemistry.

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Section: Emerging Biocatalysis Research Areas Methodologies and Toolsmentioning

confidence: 99%

Biocatalysis as Key to Sustainable Industrial Chemistry

Alcántara

Marı́a²,

Littlechild

et al. 2022

ChemSusChem

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“… 45 , 46 Ca MES-containing cells ( E. coli Δmtn) grown in the presence of N α-methyl fluoro-TMH ( 4 : F-TMH, Figure 2 ) instead of TMH produced N α-methyl fluoro ergothioneine ( 3 : F-ERG, m / z calcd: 248.0864; obsd: 248.086) with yields that correlate with the concentration of F-TMH in the medium ( Figure S8 ). Since F-TMH is an exclusively synthetic compound, 47 we can eliminate any possibility that the detected F-ERG originates from the growth medium instead from de novo biosynthesis by Ca MES. Finally, since Ca ME is translated from a synthetic codon-optimized gene, we can also exclude the possibility that the foreign nucleic acid instead of the translated protein is responsible for the sulfurization of TMH in E. coli .…”

Section: Resultsmentioning

confidence: 99%

“…Isotopologues of ergothioneine and F-TMH were produced and characterized as described in previous work. 20 , 47 …”

Section: Methodsmentioning

confidence: 99%

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Discovery and Characterization of the Metallopterin-Dependent Ergothioneine Synthase from Caldithrix abyssi

Beliaeva

Seebeck

2022

JACS Au

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Ergothioneine is a histidine derivative with a 2-mercaptoimidazole side chain and a trimethylated α-amino group. Although the physiological function of this natural product is not yet understood, the facts that many bacteria, some archaea, and most fungi produce ergothioneine and that plants and animals have specific mechanisms to absorb and distribute ergothioneine in specific tissues suggest a fundamental role in cellular life. The observation that ergothioneine biosynthesis has emerged multiple times in molecular evolution points to the same conclusion. Aerobic bacteria and fungi attach sulfur to the imidazole ring of trimethylhistidine via an O 2 -dependent reaction that is catalyzed by a mononuclear non-heme iron enzyme. Green sulfur bacteria and archaea use a rhodanese-like sulfur transferase to attach sulfur via oxidative polar substitution. In this report, we describe a third unrelated class of enzymes that catalyze sulfur transfer in ergothioneine production. The metallopterin-dependent ergothioneine synthase from Caldithrix abyssi contains an N-terminal module that is related to the tungsten-dependent acetylene hydratase and a C-terminal domain that is a functional cysteine desulfurase. The two modules cooperate to transfer sulfur from cysteine onto trimethylhistidine. Inactivation of the C-terminal desulfurase blocks ergothioneine production but maintains the ability of the metallopterin to exchange sulfur between ergothioneine and trimethylhistidine. Homologous bifunctional enzymes are encoded exclusively in anaerobic bacterial and archaeal species.

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“…Another approach for SAM regeneration uses the reverse reaction of a halide MT (E.C. 2.1.1.165) to directly re‐methylate SAH using methyl iodide with up to 500 TTN; [64] this has been expanded to the use of other alkyl halides for general alkylation [65–68] . Both regeneration systems have in common that they rely on SAH formed in the MT reaction.…”

Section: Introductionmentioning

confidence: 99%

Biomimetic S‐Adenosylmethionine Regeneration Starting from Multiple Byproducts Enables Biocatalytic Alkylation with Radical SAM Enzymes**

et al. 2023

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S‐Adenosylmethionine (SAM) is an enzyme cofactor involved in methylation, aminopropyl transfer, and radical reactions. This versatility renders SAM‐dependent enzymes of great interest in biocatalysis. The usage of SAM analogues adds to this diversity. However, high cost and instability of the cofactor impedes the investigation and usage of these enzymes. While SAM regeneration protocols from the methyltransferase (MT) byproduct S‐adenosylhomocysteine are available, aminopropyl transferases and radical SAM enzymes are not covered. Here, we report a set of efficient one‐pot systems to supply or regenerate SAM and SAM analogues for all three enzyme classes. The systems’ flexibility is showcased by the transfer of an ethyl group with a cobalamin‐dependent radical SAM MT using S‐adenosylethionine as a cofactor. This shows the potential of SAM (analogue) supply and regeneration for the application of diverse chemistry, as well as for mechanistic studies using cofactor analogues.

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FluorinatedS‐Adenosylmethionine as a Reagent for Enzyme‐Catalyzed Fluoromethylation

Cited by 8 publications

References 83 publications

Biocatalysis as Key to Sustainable Industrial Chemistry

Biocatalysis as Key to Sustainable Industrial Chemistry

Discovery and Characterization of the Metallopterin-Dependent Ergothioneine Synthase from Caldithrix abyssi

Biomimetic S‐Adenosylmethionine Regeneration Starting from Multiple Byproducts Enables Biocatalytic Alkylation with Radical SAM Enzymes**

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