The current industrial production of polymer building blocks such as ε‐caprolactone (ε‐CL) and 6‐hydroxyhexanoic acid (6HA) is a multi‐step process associated with critical environmental issues such as the generation of toxic waste and high energy consumption. Consequently, there is a demand for more eco‐efficient and sustainable production routes. This study deals with the generation of a platform organism that converts cyclohexane to such polymer building blocks without the formation of byproducts and under environmentally benign conditions. Based on kinetic and thermodynamic analyses of the individual enzymatic steps, a 4‐step enzymatic cascade in Pseudomonas taiwanensis VLB120 is rationally engineered via stepwise biocatalyst improvement on the genetic level. It is found that the intermediate product cyclohexanol severely inhibits the cascade which could be optimized by enhancing the expression level of downstream enzymes. The integration of a lactonase enables exclusive 6HA formation without side products. The resulting biocatalyst shows a high activity of 44.8 ± 0.2 U gCDW−1 and fully converts 5 mm cyclohexane to 6HA within 3 h. This platform organism can now serve as a basis for the development of greener production processes for polycaprolactone and related polymers.
Cytochrome P450 monooxygenases (Cyps) effectively catalyze the regiospecific oxyfunctionalization of inert C-H bonds under mild conditions. Due to their cofactor dependency and instability in isolated form, oxygenases are preferably applied in living microbial cells with Pseudomonas strains constituting potent host organisms for Cyps. This study presents a holistic genetic engineering approach, considering gene dosage, transcriptional, and translational levels, to engineer an effective Cyp-based whole-cell biocatalyst, building on recombinant Pseudomonas taiwanensis VLB120 for cyclohexane hydroxylation. A lac-based regulation system turned out to be favorable in terms of orthogonality to the host regulatory network and enabled a remarkable specific whole-cell activity of 34 U g CDW −1. The evaluation of different ribosomal binding sites (RBSs) revealed that a moderate translation rate was favorable in terms of the specific activity. An increase in gene dosage did only slightly elevate the hydroxylation activity, but severely impaired growth and resulted in a large fraction of inactive Cyp. Finally, the introduction of a terminator reduced leakiness. The optimized strain P. taiwanensis VLB120 pSEVA_Cyp allowed for a hydroxylation activity of 55 U g CDW −1. Applying 5 mM cyclohexane, molar conversion and biomass-specific yields of 82.5% and 2.46 mmol cyclohexanol g biomass −1 were achieved, respectively. The strain now serves as a platform to design in vivo cascades and bioprocesses for the production of polymer building blocks such as ε-caprolactone.
The current industrial production of polymer building blocks such as ε-caprolactone (ε-CL) and 6-hydroxyhexanoic acid (6HA) is a multi-step process associated with critical environmental issues such as the generation of toxic waste and high energy consumption. Consequently, there is a demand for more eco-efficient and sustainable production routes. This study deals with the generation of a platform organism that converts cyclohexane to such polymer building blocks without the formation of byproducts and under environmentally benign conditions. Based on kinetic and thermodynamic analyses of the individual enzymatic steps, we rationally engineered a 4-step enzymatic cascade in Pseudomonas taiwanensis VLB120 via stepwise biocatalyst improvement on the genetic level. We found that the intermediate product cyclohexanol severely inhibits the cascade and optimized the cascade by enhancing the expression level of downstream enzymes. The integration of a lactonase enabled exclusive 6HA formation without side products. The resulting biocatalyst showed a high activity of 44.8 ± 0.2 U g CDW -1 and fully converted 5 mM cyclohexane to 6HA within 3 h. This platform organism can now serve as a basis for the development of greener production processes for polycaprolactone and related polymers.
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