Abstract
BackgroundSesquiterpenes are a class of natural products with a diverse range of attractive industrial proprieties. Due to economic difficulties of sesquiterpene production via extraction from plants or chemical synthesis there is interest in developing alternative and cost efficient bioprocesses. The hydrocarbon α-santalene is a precursor of sesquiterpenes with relevant commercial applications. Here, we construct an efficient Saccharomyces cerevisiae cell factory for α-santalene production.ResultsA multistep metabolic engineering strategy targeted to increase precursor and cofactor supply was employed to manipulate the yeast metabolic network in order to redirect carbon toward the desired product. To do so, genetic modifications were introduced acting to optimize the farnesyl diphosphate branch point, modulate the mevalonate pathway, modify the ammonium assimilation pathway and enhance the activity of a transcriptional activator. The approach employed resulted in an overall α-santalene yield of a 0.0052 Cmmol (Cmmol glucose)-1 corresponding to a 4-fold improvement over the reference strain. This strategy, combined with a specifically developed continuous fermentation process, led to a final α-santalene productivity of 0.036 Cmmol (g biomass)-1 h-1.ConclusionsThe results reported in this work illustrate how the combination of a metabolic engineering strategy with fermentation technology optimization can be used to obtain significant amounts of the high-value sesquiterpene α-santalene. This represents a starting point toward the construction of a yeast “sesquiterpene factory” and for the development of an economically viable bio-based process that has the potential to replace the current production methods.
Highlights
Sesquiterpenes are a class of natural products with a diverse range of attractive industrial proprieties
The primary objective of this study was to enhance the availability of intracellular farnesyl diphosphate (FPP) to increase the production level of the sesquiterpene α-santalene and to evaluate the metabolic response of S. cerevisiae to the genetic modifications
Characterization of engineered sesquiterpene producing strains in two-phase chemostat cultivation S. cerevisiae was engineered to produce α-santalene by introducing the expression plasmid pISP15 containing a copy of tHMG1 and codon optimized santalene synthase (SanSyn) (SanSynopt) under control of the PGK1 and TEF1 promoters, respectively
Summary
Sesquiterpenes are a class of natural products with a diverse range of attractive industrial proprieties. Limitations in raw material accessibility, low yields and high costs of the current isoprenoid production through plant extraction or difficulties with chemical synthesis have the MVA pathway in purely oxidative growth conditions can be summarized as: À4:5 C6H12O6 À 9 ATP À 6 NADPH þ C15H24 þ. We undertook a multistep metabolic engineering strategy combining four different approaches to increase α-santalene production. These included: (i) Modulation and optimization of the FPP branch point (ii) Modulation of the MVA pathway to increase the precursor pool for isoprenoid synthesis (iii) Increasing the availability of the reductive cofactor NADPH by modifying the ammonium assimilation pathway and (iv) Enhancing the activity of a transcriptional activator of sterol biosynthesis
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