Accelerating itaconic acid production by increasing membrane permeability of whole-cell biocatalyst based on a psychrophilic bacterium Shewanella livingstonensis Ac10

•Cell membrane permeability restricts whole-cell catalysis of itaconic acid.•Psychrophile-based biocatalyst membrane permeability increased after heat treatment.•Itaconic acid biocatalysis increased approximately 6-fold after heat treatment.•Psychrophile-based biocatalyst could be recycled after ita...

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Bibliographic Details
Published in:Journal of biotechnology 2020-03, Vol.312, p.56-62
Main Authors: Luo, Gonglinfeng, Fujino, Miho, Nakano, Sho, Hida, Akiko, Tajima, Takahisa, Kato, Junichi
Format: Article
Language:English
Subjects:
Heat treatment
Itaconic acid
Membrane permeability
Psychrophile
Shewanella livingstonensis
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Summary:•Cell membrane permeability restricts whole-cell catalysis of itaconic acid.•Psychrophile-based biocatalyst membrane permeability increased after heat treatment.•Itaconic acid biocatalysis increased approximately 6-fold after heat treatment.•Psychrophile-based biocatalyst could be recycled after itaconic acid production. Whole-cell biocatalysts have numerous advantages including ease of preparation and coenzyme recovery over purified industrially used enzymes. However, the cell membrane can occasionally hinder cytoplasmic diffusion of the substrate, resulting in reduced biotransformation efficiency. Psychrophiles can grow and reproduce at low temperatures; their cell membranes are highly flexible, and their permeability can be improved via heat treatment at a moderate temperature. The aim of this study was to generate a psychrophile-based simple biocatalyst (PSCats) using Shewanella livingstonensis Ac10. This biocatalyst contained two enzymes that were heterologously expressed and converted citric acid to itaconic acid, thereby serving as a potential platform replacing the petroleum-based counterparts. The efficiency of the biocatalyst was increased via heat treatment at 45 °C for 15 min, and itaconic acid productivity of the cells after heat treatment (1.41 g/L/h) was increased around 6-fold in comparison with those without heat treatment (0.22 g/L/h). A large part of the productivity remained (67.3 %) when the cells were reused for 5 times (10 h for each reaction). Therefore, the potential of this heat-permeabilized psychrophile host to increase the productivity of whole-cell biocatalyst was proved; however, further research is necessary to understand the underlying mechanism.
ISSN:0168-1656
1873-4863
DOI:10.1016/j.jbiotec.2020.03.003