Natural Variation in the ‘Control Loop’ of BVMOAFL210 and Its Influence on Regioselectivity and Sulfoxidation

Tolmie, Carmien; Aido-Machado, Rodolpho do; Ferroni, Felix Martín; Smit, Martha S.; Opperman, Diederik J.

doi:10.3390/catal10030339

“…[33] BVMOs are versatile enzymes whose catalytic activity can be employed to synthesise valuable heteroatom-bearing chiral building blocks by non-BV processes.F or example, they are known to catalyse the oxidation of aw ide range of heteroatoms including nitrogen, selenium, boron, phosphorus,a nd sulfur. [34] Codexis used this reactivity in their largescale synthesis of the chiral sulfoxide Esomeprazole,using an engineered BVMO to circumvent problems associated with the previously used Kagan-Sharpless-Pitchen type oxida-…”

Section: Angewandte Chemiementioning

confidence: 99%

Enzymatic Kinetic Resolution by Addition of Oxygen

Harwood

¹

,

Wong

²

,

Robertson

³

2020

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Kinetic resolution using biocatalysis has proven to be an excellent complementary technique to traditional asymmetric catalysis for the production of enantioenriched compounds. Resolution using oxidative enzymes produces valuable oxygenated structures for use in synthetic route development. This Minireview focuses on enzymes which catalyse the insertion of an oxygen atom into the substrate and, in so doing, can achieve oxidative kinetic resolution. The Baeyer-Villiger rearrangement, epoxidation, and hydroxylation are included, and biological advancements in enzyme development, and applications of these key enantioenriched intermediates in natural product synthesis are discussed. Scheme 1-Representative early examples of enzymatic OKR. Lucy Harwood received her MSci degree in Chemistry from Queen's University, Belfast completing her final year research project on the use of sigmatropic rearrangements in synthesis in the group of Prof. P. Stevenson. She is currently conducting her doctoral studies at the University of Oxford in the groups of Prof. J. Robertson and Prof. L.-L. Wong developing mutant cytochrome P450s as general oxidation catalysts.

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“…Staying with the industrial application theme of BVMOs, Tolmie et al [6] discuss the natural variation in the "control loop" of another BVMO, BVMO AF210 from Aspergillus flavons and its influence on regioselectivity and sulfoxidation. The authors note that with the exception of directed evolution studies influencing the substrate scope and selectivity/specificity through allosteric effects, protein engineering of BVMOs to improve substrate acceptance or regio-, enantio-, and stereospecificity/selectivity has mostly focused on "hot spot" residues lining the active site.…”

mentioning

confidence: 99%

Editorial: Special Issue on “Flavin Monooxygenases”

Gilardi¹,

Sadeghi²

2021

Catalysts

0

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show abstract

Enzymatic Kinetic Resolution by Addition of Oxygen

Harwood

¹

,

Wong

²

,

Robertson

³

2020

View full text Add to dashboard Cite

Kinetic resolution using biocatalysis has proven to be an excellent complementary technique to traditional asymmetric catalysis for the production of enantioenriched compounds. Resolution using oxidative enzymes produces valuable oxygenated structures for use in synthetic route development. This Minireview focuses on enzymes which catalyse the insertion of an oxygen atom into the substrate and, in so doing, can achieve oxidative kinetic resolution. The Baeyer–Villiger rearrangement, epoxidation, and hydroxylation are included, and biological advancements in enzyme development, and applications of these key enantioenriched intermediates in natural product synthesis are discussed.

show abstract

Natural Variation in the ‘Control Loop’ of BVMOAFL210 and Its Influence on Regioselectivity and Sulfoxidation

Cited by 3 publications

References 43 publications

Enzymatic Kinetic Resolution by Addition of Oxygen

Enzymatic Kinetic Resolution by Addition of Oxygen

Editorial: Special Issue on “Flavin Monooxygenases”

Enzymatic Kinetic Resolution by Addition of Oxygen

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