Metabolic engineering of Saccharomyces cerevisiae for enhanced production of caffeic acid

As a natural phenolic acid product of plant source, caffeic acid displays diverse biological activities and acts as an important precursor for the synthesis of other valuable compounds. Limitations in chemical synthesis or plant extraction of caffeic acid trigger interest in its microbial biosynthes...

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Bibliographic Details
Published in:Applied microbiology and biotechnology 2021-08, Vol.105 (14-15), p.5809-5819
Main Authors: Zhou, Pingping, Yue, Chunlei, Shen, Bin, Du, Yi, Xu, Nannan, Ye, Lidan
Format: Article
Language:English
Subjects:
Acid production
Acids
Analysis
Biomedical and Life Sciences
Biosynthesis
Biotechnological Products and Process Engineering
Biotechnology
Brewer's yeast
Caffeic acid
Chemical compounds
Chemical synthesis
Combinatorial analysis
Feedback
Feedback inhibition
Food irradiation
Gene expression
Genes
Genetic aspects
Genomics
Life Sciences
Metabolic engineering
Metabolites
Methods
Microbial Genetics and Genomics
Microbiology
Microorganisms
Phenolic acids
Phenols
Physiological aspects
Plant extracts
Precursors
Saccharomyces cerevisiae
Stability
Tyrosine
Yeast
Yeasts
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Summary:As a natural phenolic acid product of plant source, caffeic acid displays diverse biological activities and acts as an important precursor for the synthesis of other valuable compounds. Limitations in chemical synthesis or plant extraction of caffeic acid trigger interest in its microbial biosynthesis. Recently, Saccharomyces cerevisiae has been reported for the biosynthesis of caffeic acid via episomal plasmid-mediated expression of pathway genes. However, the production was far from satisfactory and even relied on the addition of precursor. In this study, we first established a controllable and stable caffeic acid pathway by employing a modified GAL regulatory system to control the genome-integrated pathway genes in S. cerevisiae and realized biosynthesis of 222.7 mg/L caffeic acid. Combinatorial engineering strategies including eliminating the tyrosine-induced feedback inhibition, deleting genes involved in competing pathways, and overexpressing rate-limiting enzymes led to about 2.6-fold improvement in the caffeic acid production, reaching up to 569.0 mg/L in shake-flask cultures. To our knowledge, this is the highest ever reported titer of caffeic acid synthesized by engineered yeast. This work showed the prospect for microbial biosynthesis of caffeic acid and laid the foundation for constructing biosynthetic pathways of its derived metabolites. Key points Genomic integration of ORgTAL , OHpaB , and HpaC for caffeic acid production in yeast. Feedback inhibition elimination and Aro10 deletion improved caffeic acid production. The highest ever reported titer (569.0 mg/L) of caffeic acid synthesized by yeast.
ISSN:0175-7598
1432-0614
DOI:10.1007/s00253-021-11445-1