Systematic engineering enables efficient biosynthesis of L-phenylalanine in E. coli from inexpensive aromatic precursors

• Published in: Microbial cell factories Vol. 23; no. 1; p. 12
• Main Authors: Nie, Mengzhen, Wang, Jingyu, Chen, Zeyao, Cao, Chenkai, Zhang, Kechun
• Format: Journal Article
• Language: English
• Published: England BioMed Central Ltd 05.01.2024; BioMed Central; BMC
• Subjects: Alcohol; Aldehydes; Aldolase; Amino acids; Aromatic precursors; Benzaldehyde; Benzaldehydes; Benzyl Alcohol; Bioconversion; Biosynthesis; Chemical synthesis; Cloning; Dehydration; Dehydrogenases; E coli; Engineering; Enzymes; Escherichia coli; Escherichia coli - genetics; Evaluation; Glycine; L-phenylalanine; Microorganisms; Modules; Phenylalanine; Physiological aspects; Plasmids; Precursors; Properties; Reducing Agents; Threonine aldolase; Threonine dehydratase; China; Engineering; L-phenylalanine; Benzyl alcohol; Aromatic precursors; Escherichia coli; Benzaldehyde
• ISSN: 1475-2859; 1475-2859
• DOI: 10.1186/s12934-023-02282-0

L-phenylalanine is an essential amino acid with various promising applications. The microbial pathway for L-phenylalanine synthesis from glucose in wild strains involves lengthy steps and stringent feedback regulation that limits the production yield. It is attractive to find other candidates, which could be used to establish a succinct and cost-effective pathway for L-phenylalanine production. Here, we developed an artificial bioconversion process to synthesize L-phenylalanine from inexpensive aromatic precursors (benzaldehyde or benzyl alcohol). In particular, this work opens the possibility of L-phenylalanine production from benzyl alcohol in a cofactor self-sufficient system without any addition of reductant. The engineered L-phenylalanine biosynthesis pathway comprises two modules: in the first module, aromatic precursors and glycine were converted into phenylpyruvate, the key precursor for L-phenylalanine. The highly active enzyme combination was natural threonine aldolase LtaE and threonine dehydratase A8H , which could produce phenylpyruvate in a titer of 4.3 g/L. Overexpression of gene ridA could further increase phenylpyruvate production by 16.3%, reaching up to 5 g/L. The second module catalyzed phenylpyruvate to L-phenylalanine, and the conversion rate of phenylpyruvate was up to 93% by co-expressing PheDH and FDH . Then, the engineered E. coli containing these two modules could produce L-phenylalanine from benzaldehyde with a conversion rate of 69%. Finally, we expanded the aromatic precursors to produce L-phenylalanine from benzyl alcohol, and firstly constructed the cofactor self-sufficient biosynthetic pathway to synthesize L-phenylalanine without any additional reductant such as formate. Systematical bioconversion processes have been designed and constructed, which could provide a potential bio-based strategy for the production of high-value L-phenylalanine from low-cost starting materials aromatic precursors.