One‐Pot Bioconversion of l‐Arabinose to l‐Ribulose in an Enzymatic Cascade

This work reports the one‐pot enzymatic cascade that completely converts l‐arabinose to l‐ribulose using four reactions catalyzed by pyranose 2‐oxidase (P2O), xylose reductase, formate dehydrogenase, and catalase. As wild‐type P2O is specific for the oxidation of six‐carbon sugars, a pool of P2O var...

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Published in	Angewandte Chemie Vol. 131; no. 8; pp. 2450 - 2454
Main Authors	Chuaboon, Litavadee, Wongnate, Thanyaporn, Punthong, Pangrum, Kiattisewee, Cholpisit, Lawan, Narin, Hsu, Chia‐Yi, Lin, Chun‐Hung, Bornscheuer, Uwe T., Chaiyen, Pimchai
Format	Journal Article
Language	English
Published	Weinheim Wiley Subscription Services, Inc 18.02.2019
Subjects	Arabinose Bioconversion Cascade chemical reactions Catalase Chemical reactions Chemistry Computer applications Eintopfreaktionen Enzymes Enzymkaskaden Flavin Flavoenzyme Formate dehydrogenase Molecular dynamics Oxidase Oxidation Quantum mechanics Reduction Ribulose Steric effects Sugar Xylose Xylose reductase
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Abstract	This work reports the one‐pot enzymatic cascade that completely converts l‐arabinose to l‐ribulose using four reactions catalyzed by pyranose 2‐oxidase (P2O), xylose reductase, formate dehydrogenase, and catalase. As wild‐type P2O is specific for the oxidation of six‐carbon sugars, a pool of P2O variants was generated based on rational design to change the specificity of the enzyme towards the oxidation of l‐arabinose at the C2‐position. The variant T169G was identified as the best candidate, and this had an approximately 40‐fold higher rate constant for the flavin reduction (sugar oxidation) step, as compared to the wild‐type enzyme. Computational calculations using quantum mechanics/molecular mechanics (QM/MM) molecular dynamics (MD) showed that this improvement is due to a decrease in the steric effects at the axial C4‐OH of l‐arabinose, which allows a reduction in the distance between the C2‐H and flavin N5, facilitating hydride transfer and enabling flavin reduction. Süßer Eintopf: Ein neues Konzept für die Synthese von l‐Ribulose aus l‐Arabinose beruht auf einer Eintopf‐Biokonversion mithilfe einer optimierten Pyranose‐2‐Oxidase, Xylose‐Reduktase, Formiat‐Dehydrogenase und Katalase. Laut Kinetikmessungen und MD‐Simulationen befindet sich das Zuckersubstrat in der künstlichen Pyranose‐2‐Oxidase näher an der FAD‐N5‐Position als im Wildtyp.
AbstractList	This work reports the one‐pot enzymatic cascade that completely converts l‐arabinose to l‐ribulose using four reactions catalyzed by pyranose 2‐oxidase (P2O), xylose reductase, formate dehydrogenase, and catalase. As wild‐type P2O is specific for the oxidation of six‐carbon sugars, a pool of P2O variants was generated based on rational design to change the specificity of the enzyme towards the oxidation of l‐arabinose at the C2‐position. The variant T169G was identified as the best candidate, and this had an approximately 40‐fold higher rate constant for the flavin reduction (sugar oxidation) step, as compared to the wild‐type enzyme. Computational calculations using quantum mechanics/molecular mechanics (QM/MM) molecular dynamics (MD) showed that this improvement is due to a decrease in the steric effects at the axial C4‐OH of l‐arabinose, which allows a reduction in the distance between the C2‐H and flavin N5, facilitating hydride transfer and enabling flavin reduction. Süßer Eintopf: Ein neues Konzept für die Synthese von l‐Ribulose aus l‐Arabinose beruht auf einer Eintopf‐Biokonversion mithilfe einer optimierten Pyranose‐2‐Oxidase, Xylose‐Reduktase, Formiat‐Dehydrogenase und Katalase. Laut Kinetikmessungen und MD‐Simulationen befindet sich das Zuckersubstrat in der künstlichen Pyranose‐2‐Oxidase näher an der FAD‐N5‐Position als im Wildtyp. This work reports the one‐pot enzymatic cascade that completely converts l ‐arabinose to l ‐ribulose using four reactions catalyzed by pyranose 2‐oxidase (P2O), xylose reductase, formate dehydrogenase, and catalase. As wild‐type P2O is specific for the oxidation of six‐carbon sugars, a pool of P2O variants was generated based on rational design to change the specificity of the enzyme towards the oxidation of l ‐arabinose at the C2‐position. The variant T169G was identified as the best candidate, and this had an approximately 40‐fold higher rate constant for the flavin reduction (sugar oxidation) step, as compared to the wild‐type enzyme. Computational calculations using quantum mechanics/molecular mechanics (QM/MM) molecular dynamics (MD) showed that this improvement is due to a decrease in the steric effects at the axial C4‐OH of l ‐arabinose, which allows a reduction in the distance between the C2‐H and flavin N5, facilitating hydride transfer and enabling flavin reduction. This work reports the one‐pot enzymatic cascade that completely converts l‐arabinose to l‐ribulose using four reactions catalyzed by pyranose 2‐oxidase (P2O), xylose reductase, formate dehydrogenase, and catalase. As wild‐type P2O is specific for the oxidation of six‐carbon sugars, a pool of P2O variants was generated based on rational design to change the specificity of the enzyme towards the oxidation of l‐arabinose at the C2‐position. The variant T169G was identified as the best candidate, and this had an approximately 40‐fold higher rate constant for the flavin reduction (sugar oxidation) step, as compared to the wild‐type enzyme. Computational calculations using quantum mechanics/molecular mechanics (QM/MM) molecular dynamics (MD) showed that this improvement is due to a decrease in the steric effects at the axial C4‐OH of l‐arabinose, which allows a reduction in the distance between the C2‐H and flavin N5, facilitating hydride transfer and enabling flavin reduction.
Author	Chuaboon, Litavadee Hsu, Chia‐Yi Bornscheuer, Uwe T. Chaiyen, Pimchai Punthong, Pangrum Kiattisewee, Cholpisit Lawan, Narin Wongnate, Thanyaporn Lin, Chun‐Hung
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Snippet	This work reports the one‐pot enzymatic cascade that completely converts l‐arabinose to l‐ribulose using four reactions catalyzed by pyranose 2‐oxidase (P2O),... This work reports the one‐pot enzymatic cascade that completely converts l ‐arabinose to l ‐ribulose using four reactions catalyzed by pyranose 2‐oxidase...
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SubjectTerms	Arabinose Bioconversion Cascade chemical reactions Catalase Chemical reactions Chemistry Computer applications Eintopfreaktionen Enzymes Enzymkaskaden Flavin Flavoenzyme Formate dehydrogenase Molecular dynamics Oxidase Oxidation Quantum mechanics Reduction Ribulose Steric effects Sugar Xylose Xylose reductase
Title	One‐Pot Bioconversion of l‐Arabinose to l‐Ribulose in an Enzymatic Cascade
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