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Abstract Modular co‐culture engineering is an emerging approach for biosynthesis of complex natural products. In this study, microbial co‐cultures composed of two and threeEscherichia colistrains, respectively, are constructed for de novo biosynthesis of flavonoid acacetin, a value‐added natural compound possessing numerous demonstrated biological activities, from simple carbon substrate glucose. To this end, the heterologous biosynthetic pathway is divided into different modules, each of which is accommodated in a dedicatedE. colistrain for functional expression. After the optimization of the inoculation ratio between the constituent strains, the engineered co‐cultures show a 4.83‐fold improvement in production comparing to the mono‐culture controls. Importantly, cultivation of the three‐strain co‐culture in shake flasks result in the production of 20.3 mg L−1acacetin after 48 h. To the authors' knowledge, this is the first report on acacetin de novo biosynthesis in a heterologous microbial host. The results of this work confirm the effectiveness of modular co‐culture engineering for complex flavonoid biosynthesis.
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Increased cytoplasmic expression of PETase enzymes in E. coli
Abstract BackgroundDepolymerizing polyethylene terephthalate (PET) plastics using enzymes, such as PETase, offers a sustainable chemical recycling route. To enhance degradation, many groups have sought to engineer PETase for faster catalysis on PET and elevated stability. Considerably less effort has been focused toward expressing large quantities of the enzyme, which is necessary for large-scale application and widespread use. In this work, we evaluated severalE. colistrains for their potential to produce soluble, folded, and activeIsPETase, and moved the production to a benchtop bioreactor. As PETase is known to require disulfide bonds to be functional, we screened several disulfide-bond promoting strains ofE. colito produceIsPETase, FAST-PETase and Hot-PETase. ResultsWe found expression in SHuffle T7 Express results in higher active expression ofIsPETase compared to standardE. coliproduction strains such as BL21(DE3), reaching a purified titer of 20 mg enzyme per L of culture from shake flasks using 2xLB medium. We characterized purifiedIsPETase on 4-nitrophenyl acetate and PET microplastics, showing the enzyme produced in the disulfide-bond promoting host has high activity. Using a complex medium with glycerol and a controlled bioreactor,IsPETase titer reached 104 mg per L for a 46-h culture. FAST-PETase was found to be produced at similar levels in BL21(DE3) or SHuffle T7 Express, with purified production reaching 65 mg per L culture when made in BL21(DE3). Hot-PETase titers were greatest in BL21(DE3) reaching 77 mg per L culture. ConclusionsWe provide protein expression methods to produce three important PETase variants. Importantly, forIsPETase, changing expression host, medium optimization and movement to a bioreactor resulted in a 50-fold improvement in production amount with a per cell dry weight productivity of 0.45 mgPETasegCDW−1 h−1, which is tenfold greater than that forK. pastoris. We show that the benefit of using SHuffle T7 Express for expression only extends toIsPETase, with FAST-PETase and Hot-PETase better produced and purified from BL21(DE3), which is unexpected given the number of cysteines present. This work represents a systematic evaluation of protein expression and purification conditions for PETase variants to permit further study of these important enzymes.
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- PAR ID:
- 10556519
- Publisher / Repository:
- Springer Science + Business Media
- Date Published:
- Journal Name:
- Microbial Cell Factories
- Volume:
- 23
- Issue:
- 1
- ISSN:
- 1475-2859
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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