Rational design of a novel halotolerant ATP regeneration system for biocatalytic CTP production

BACKGROUND Acetyl phosphate/acetate kinase system is a cost‐saving and efficient ATP regeneration system. However, it suffers from accumulation of salts during catalytic reactions. It inhibits the activity of acetate kinase (ACK), a crucial enzyme of this process, and hence decreases the rate of pro...

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Published in:Journal of chemical technology and biotechnology (1986) 2023-04, Vol.98 (4), p.1025-1031
Main Authors: Zhang, Jie, Sun, Chenlei, Wen, Qingshi, Miao, Rongxin, Zhang, Bingyun, Yan, Ziyi, Ying, Hanjie, Liu, Dong, Wang, Junzhi
Format: Article
Language:English
Subjects:
Accumulation
Acetate kinase
Acetic acid
Acetyl phosphate
Adenosine triphosphate
ATP
ATP regeneration system
cascade biocatalysis
Chemical compounds
CTP
CTP production
Cytidine triphosphate
Design
Design optimization
Enzymes
halotolerant
Kinases
rational design
Regeneration
Residues
Salinity tolerance
Salts
surface protein
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Summary:BACKGROUND Acetyl phosphate/acetate kinase system is a cost‐saving and efficient ATP regeneration system. However, it suffers from accumulation of salts during catalytic reactions. It inhibits the activity of acetate kinase (ACK), a crucial enzyme of this process, and hence decreases the rate of product accumulation and yield of CTP. RESULTS A new halotolerant ACK enzyme based ATP regeneration platform was established in this research by applying the concept of rational design to optimize its building blocks. Selection of residues for rational design followed several rules. First, the less conserved residue positions on the protein surface were considered. Second, avoiding significant residue interactions, suchas salt bridges. Third, following the feature of nature occurring halotolerant enzymes, the basic and neutral surface residues were replaced with acidic ones. Our mutants represent high catalytic activities and high IC50 value (inhibit activity by 50%) at high salt concentrations. Also, when the halotolerant ACK was applied to catalyze CTP production, the maximum titer was 213.5 ± 1.6 mM (which is 12.3‐fold higher than that of the traditional process), the productivity was 13.3 ± 0.1 mM L−1 h−1, and the molar yield to 5′‐cytidylate monophosphate (CMP) and utilization efficiency of energy were 92.4% and 72.7%, respectively. CONCLUSION This strategy can be applied to modify other enzymes in the industry and gives insight into resolving salt accumulation during biocatalytic processes. In addition, the halotolerant Adenosine Triphosphate (ATP) regeneration system built in this work can be applied to the synthesis of several other high energy compounds. © 2023 Society of Chemical Industry (SCI).
ISSN:0268-2575
1097-4660
DOI:10.1002/jctb.7310