Computational and Experimental Engineering of <i>trans</i>-Anethole Oxygenase for Enhancing Activity in Industrial Vanillin Biosynthesis

Computational and Experimental Engineering of <i>trans</i>-Anethole Oxygenase for Enhancing Activity in Industrial Vanillin Biosynthesis

Vanillin, a widely used aromatic compound, can be biocatalytically synthesized using <i>trans</i>-anethole oxygenase (TAO). However, wild-type TAO shows low activity and stability. This study utilized AlphaFold2/3 modeling, molecular docking, and MD simulations to identify key residues (...

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Bibliographic Details
Main Author: Qi Ye (243032) (author)
Other Authors: Fan Zhao (385132) (author), Hongjia Wei (21602296) (author), Yupei Tang (21602299) (author), Yongbo Song (1547986) (author), Weizhuo Xu (18080677) (author)
Published: 2025
Subjects:
Biophysics
Biochemistry
Computational Biology
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Information Systems not elsewhere classified
sustainable vanillin production
increasing protein flexibility
identify key residues
energy decomposition indicated
biocatalytically synthesized using
>- anethole oxygenase
study utilized alphafold2
improve tao ’
f34y reaching 88
tao ).
study demonstrates
mutants f34y
trans </
substrate binding
seven mutants
optimizing biocatalysts
offers insights
mutation library
molecular docking
md simulations
heme coordination
experimentally tested
experimental engineering
enhancing activity
catalytic performance
bond networks
7 %.
40 %,
3 modeling
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Summary:Vanillin, a widely used aromatic compound, can be biocatalytically synthesized using <i>trans</i>-anethole oxygenase (TAO). However, wild-type TAO shows low activity and stability. This study utilized AlphaFold2/3 modeling, molecular docking, and MD simulations to identify key residues (R86, T90, and H118) involved in substrate binding and catalysis. A multiplatform computational design strategy (PROSS, FireProt, Rosetta, and FoldX) was used to generate a mutation library, from which seven mutants were experimentally tested. Mutants F34Y, G117I, and T138L increased vanillin yield by over 40%, with F34Y reaching 88.7%. Energy decomposition indicated that these mutations enhanced substrate stabilization and heme coordination. F34Y remodeled distal H-bond networks, while G117I and T138L improved HEM stability. In contrast, N144L impaired catalytic efficiency by increasing protein flexibility. This study demonstrates an effective enzyme engineering strategy to improve TAO’s catalytic performance and offers insights for optimizing biocatalysts in sustainable vanillin production.

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