Metabolic engineering of S. cerevisiae for the production of flavonoids
Doktorsavhandling, 2023
The aim of this thesis was to apply different strategies to engineer S. cerevisiae to establish and optimize the production of the flavonoids pinocembrin and naringenin, and their derivatives. Different approaches were used: different heterologous genes were screened, their copy number was increased to achieve the highest production, the competing pathways were eliminated, and the precursors availability was increased. Furthermore, the bottlenecks of the pathways were identified. For pinocembrin production, I established that the accumulation of the toxic intermediate cinnamic acid limits production. Therefore, the transcriptional changes that S. cerevisiae undergoes under aromatic acid stress were investigated. My findings indicate that by employing transcription factor engineering it is possible to develop strains that are tolerant to aromatic compounds that can be utilized for the production of valuable natural products. When analysing the naringenin biosynthetic pathway it was found that the distribution of the pathway intermediates in the cell is a major issue. The spatiotemporal distribution of p-coumaric acid (a key pathway intermediate) and naringenin was assessed and it was determined that p-coumaric acid accumulates extracellularly and cannot be fully utilized. Therefore, a dual dynamic control system that combines a malonyl-CoA biosensor regulator and an RNAi strategy was established, to autonomously control the synthesis of p-coumaric acid and downregulate the fatty acid pathways that compete directly for the precursor malonyl-CoA. Finally, the production of naringenin and pinocembrin derivatives was established including kaempferol, quercetin and baicalein which present valuable bioactivities.
Overall, this thesis employs diverse strategies for constructing and optimizing yeast factories for flavonoid production.
microbial cell factories
high-value products
sustainability
cinnamic acid
plant natural products
Genetic engineering
yeast
Författare
Marta Tous Mohedano
Chalmers, Life sciences, Systembiologi
Optimization of Pinocembrin Biosynthesis in Saccharomyces cerevisiae
ACS Synthetic Biology,;Vol. 12(2023)p. 144-152
Artikel i vetenskaplig tidskrift
Tous-Mohedano, M., Konzock, O., Yu, R., and Chen, Y. Improving the aromatic acid tolerance of S. cerevisiae by transcriptomics analysis and transcription factor engineering
Fine-tuning of p-coumaric acid synthesis to increase (2S)-naringenin production in yeast
Metabolic Engineering,;Vol. 79(2023)p. 192-202
Artikel i vetenskaplig tidskrift
Optimizing yeast for high-level production of kaempferol and quercetin
Microbial Cell Factories,;Vol. 22(2023)
Artikel i vetenskaplig tidskrift
Microorganisms, such as the yeast S. cerevisiae, present an alternative opportunity to produce flavonoids. S. cerevisiae, known as baker’s yeast, has been traditionally used to produce beer, wine, and bread. In the last decades and with the development of genetic engineering, yeast has also been used as a microbial cell factory to produce commodity chemicals, fuel substitutes, pharmaceutical drugs, and natural products.
The research included in this thesis optimizes the production of two types of flavonoids: pinocembrin, naringenin in S. cerevisiae. By genetic engineering, I introduced efficient enzymes that catalyse the production of the flavonoids, increased the cellular supply of precursor molecules, and eliminated or regulated biological pathways in yeast that competed with the flavonoid production. I also addressed challenges that limit flavonoid production. For example, in the pinocembrin synthesis pathway, S. cerevisiae is exposed to toxic flavonoid precursor (cinnamic acid). To solve this problem, we looked into the genetic response of S. cerevisiae when it grows in the presence of the toxic compound cinnamic acid and overexpress or delete genes that mitigated the toxicity. In the naringenin pathway, we found that yeast secretes the important precursor p-coumaric acid and therefore cannot utilize it effectively for naringenin production. Therefore, we developed a method to control the pathway and increased the availability of the precursor. Finally, we scaled up flavonoid production from shake flask to 1-L bioreactors in several flavonoid production strains, taking a first step from lab bench towards the construction of microbial factories.
Altogether this thesis demonstrates the potential of S. cerevisiae as an alternative to conventional extraction-based processes to produce flavonoids and presents several strategies to optimize their production in yeast.
Infrastruktur
Chalmers infrastruktur för masspektrometri
Ämneskategorier
Livsmedelsvetenskap
Biologiska vetenskaper
Bioinformatik och systembiologi
Fundament
Grundläggande vetenskaper
Styrkeområden
Hälsa och teknik
ISBN
978-91-7905-883-8
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5349
Utgivare
Chalmers
KC-salen, Kemigården 4, Chalmers
Opponent: Professor Paola Branduardi, Università degli Studi di Milano-Bicocca, Italy