Improvement of catechin production in Escherichia coli through combinatorial metabolic engineering

Reconstruction of highly efficient biosynthesis pathways is essential for the production of valuable plant secondary metabolites in recombinant microorganisms. In order to improve the titer of green tea catechins in Escherichia coli, combinatorial strategies were employed using the ePathBrick vector...

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Bibliographic Details
Published in:Metabolic engineering 2015-03, Vol.28, p.43-53
Main Authors: Zhao, Shujuan, Jones, J. Andrew, Lachance, Daniel M., Bhan, Namita, Khalidi, Omar, Venkataraman, Sylesh, Wang, Zhengtao, Koffas, Mattheos A.G.
Format: Article
Language:English
Subjects:
Catechin
Catechin - biosynthesis
Catechin - genetics
Copy number balancing
ePathBrick
Escherichia coli - genetics
Escherichia coli - metabolism
Metabolic Engineering
Mixed Function Oxygenases - biosynthesis
Mixed Function Oxygenases - genetics
NADP - biosynthesis
NADP - genetics
NADPH availability
Pathway optimization
Plant Proteins - biosynthesis
Plant Proteins - genetics
Protein scaffolds
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Summary:Reconstruction of highly efficient biosynthesis pathways is essential for the production of valuable plant secondary metabolites in recombinant microorganisms. In order to improve the titer of green tea catechins in Escherichia coli, combinatorial strategies were employed using the ePathBrick vectors to express the committed catechin pathway: flavanone 3β-hydroxylase (F3H), dihydroflavonol 4-reductase (DFR), and leucoanthocyanidin reductase (LAR). Three F3H, three DFR, and two LAR genes originating from different plant species were selected and synthesized, to create 18 pathway variants to be screened in E. coli. Constructs containing F3Hsyn originally from Camellia sinensis, DFRsyn from Anthurium andraeanum, C. sinensis, or Fragaria ananass, and LARsyn from Desmodium uncinatum (p148, p158 and p168) demonstrated high conversion efficiency with either eriodictyol or naringenin as substrate. A highly efficient construct was created by assembling additional copies of DFRsyn and LARsyn enabling a titer of 374.6±43.6mg/L of (+)-catechin. Improving the NADPH availability via the ΔpgiΔppc mutation, BLΔpgiΔppc-p148 produced the highest titer of catechin at 760.9±84.3mg/L. After utilizing a library of scaffolding proteins, the strain BLΔpgiΔppc-p168-759 reached the highest titer of (+)-catechin of 910.9±61.3mg/L from 1.0g/L of eriodictyol in batch culture with M9 minimal media. The impact of oxygen availability on the biosynthesis of catechin was also investigated. •18 pathways from homologous enzymes were constructed for catechin production.•Three basic pathways demonstrated the highest substrate conversion efficiency.•Additional copies of DFR and LAR enabled increases in conversion efficiency.•Application of a scaffolding library further improved (+)-catechin titers.
ISSN:1096-7176
1096-7184
DOI:10.1016/j.ymben.2014.12.002