Abstract
Methyl ketones present a group of highly reduced platform chemicals
industrially produced from petroleum-derived hydrocarbons. They find
applications in the fragrance, flavor, pharmacological, and agrochemical
industries, and are further discussed as biodiesel blends. In recent
years, intense research has been carried out to achieve sustainable
production of these molecules by re-arranging the fatty acid metabolism
of various microbes. One challenge in the development of a highly
productive microbe is the high demand for reducing power. Here, we
engineered Pseudomonas taiwanensis VLB120 for methyl ketone
production as this microbe has been shown to sustain exceptionally high
NAD(P)H regeneration rates. The implementation of published strategies
resulted in 2.1 g Laq−1 methyl ketones in
fed-batch fermentation. We further increased the production by
eliminating competing reactions suggested by metabolic analyses. These
efforts resulted in the production of 9.8 g Laq−1 methyl ketones (corresponding to 69.3 g Lorg−1 in the in situ
extraction phase) at 53% of the maximum theoretical yield. This
represents a 4-fold improvement in product titer compared to the initial
production strain and the highest titer of recombinantly produced
methyl ketones reported to date. Accordingly, this study underlines the
high potential of P. taiwanensis VLB120 to produce methyl
ketones and emphasizes model-driven metabolic engineering to rationalize
and accelerate strain optimization efforts.
Original language | English |
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Journal | Metabolic Engineering |
Volume | 62 |
Pages (from-to) | 84-94 |
ISSN | 1096-7176 |
DOIs | |
Publication status | Published - 2020 |
Keywords
- Biodiesel
- Pseudomonads
- Thioesterase
- Metabolic modeling
- Metabolic engineering
- Synthetic biology