Engineering of Integral Membrane Metalloenzyme UndB and Designing of a Cell-Free Biocatalytic Platform Enabled Efficient 1‑Alkene Production

Engineering of Integral Membrane Metalloenzyme UndB and Designing of a Cell-Free Biocatalytic Platform Enabled Efficient 1‑Alkene Production

The bioproduction of 1-alkenes is of significant global interest due to their potential as green commodity chemicals and next-generation ‘drop-in’ biofuels. Here, we report an engineering strategy to enhance the catalytic activity and substrate specificity of the membrane-bound metalloenzyme UndB, s...

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Bibliographic Details
Main Author: Tabish Iqbal (5593025) (author)
Other Authors: Subhashini Murugan (17407884) (author), Jayaprakash Karupusamy (22428500) (author), Abhishek Sirohiwal (5368541) (author), Debasis Das (1344114) (author)
Published: 2025
Subjects:
Biophysics
Biochemistry
Biotechnology
Immunology
Inorganic Chemistry
Physical Sciences not elsewhere classified
green commodity chemicals
generation ‘ drop
enabling efficient long
scale simulations unveiled
free biocatalytic platform
chain fatty acids
bound metalloenzyme undb
system achieved 98
governs substrate uptake
alkene yield using
highly efficient undb
providing mechanistic insights
promising bioproduction strategy
system achieved
yield medium
simulations revealed
offering insights
highly dynamic
alkene production
undb ’
undb family
engineered undb
chain 1
biocatalytic 1
’ biofuels
undecene production
total turnover
substrate specificity
substrate recognition
structural analysis
significantly improving
precise modulation
pair network
mild conditions
key determinant
fold improvement
evolutionary adaptability
engineering strategy
crucial ion
catalytic activity
catalyst loading
04 mol
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Summary:The bioproduction of 1-alkenes is of significant global interest due to their potential as green commodity chemicals and next-generation ‘drop-in’ biofuels. Here, we report an engineering strategy to enhance the catalytic activity and substrate specificity of the membrane-bound metalloenzyme UndB, significantly improving its utility in biocatalytic 1-alkene production. We developed a highly efficient UndB-based cell-free biocatalytic platform for high-yield medium-chain 1-alkene production. This system achieved a 262-fold improvement in UndB activity toward 1-undecene production, with a total turnover of 3412. Through structural analysis of the UndB family of proteins, we engineered UndB by domain-swapping, enhancing its selectivity toward naturally abundant long-chain fatty acids, enabling efficient long-chain 1-alkene production. Our large-scale simulations unveiled a crucial ion-pair network that orchestrates substrate–protein interactions, providing a framework for substrate stabilization. We identified a highly dynamic and functionally pivotal Arg121 residue that governs substrate uptake and stabilization, providing mechanistic insights into UndB’s substrate recognition. Furthermore, simulations revealed that precise modulation of the substrate-binding pocket volume serves as the key determinant of substrate specificity across UndB variants, offering insights into the evolutionary adaptability of the UndB family. Our system achieved 98% 1-alkene yield using only 0.04 mol % catalyst loading under mild conditions, presenting a promising bioproduction strategy.

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