Improved l-phenylglycine synthesis by introducing an engineered cofactor self-sufficient system

Wang, Pengchao; Zhang, Xiwen; Tao, Yucheng; Lv, Xubing; Cheng, Shengjie; Liu, Chengwei

doi:10.1016/j.synbio.2021.12.008

Cited by 6 publications

(2 citation statements)

References 49 publications

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“…Many strategies focused on the supply and regeneration of NAD(P)H cofactor have been developed in biocatalysis and biotransformation by researchers. [ 5–10 ] For example, cheaper artificial analogs of nicotinamide cofactors have emerged as alternatives to more expensive natural nicotinamide cofactors because of their similar chemical structure [ 11 ] ; however, using artificial cofactors resulted in the enzymatic efficiencies being substantially decreased compared with the same amount of stoichiometric use of natural cofactors. Besides, NAD(P)H was recycled to regenerate under a sacrificial substrate as the electron donor by introducing a heterologous NAD(P)+ dependent enzyme coupled with NAD(P)H dependent enzyme.…”

Section: Introductionmentioning

confidence: 99%

Design of a cofactor self‐sufficient whole‐cell biocatalyst for enzymatic asymmetric reduction via engineered metabolic pathways and multi‐enzyme cascade

Zou,

Zhang,

Han

et al. 2024

Biotechnology Journal

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NAD(P)H‐dependent oxidoreductases are crucial biocatalysts for synthesizing chiral compounds. Yet, the industrial implementation of enzymatic redox reactions is often hampered by an insufficient supply of expensive nicotinamide cofactors. Here, a cofactor self‐sufficient whole‐cell biocatalyst was developed for the enzymatic asymmetric reduction of 2‐oxo‐4‐[(hydroxy)(‐methyl)phosphinyl] butyric acid (PPO) to L‐phosphinothricin (L‐PPT). The endogenous NADP+ pool was significantly enhanced by regulating Preiss‐Handler pathway toward NAD(H) synthesis and, in the meantime, introducing NAD kinase to phosphorylate NAD(H) toward NADP+. The intracellular NADP(H) concentration displayed a 2.97‐fold increase with the strategy compared with the wild‐type strain. Furthermore, a recombinant multi‐enzyme cascade biocatalytic system was constructed based on the Escherichia coli chassis. In order to balance multi‐enzyme co‐expression levels, the strategy of modulating rate‐limiting enzyme PmGluDH by RBS strengths regulation successfully increased the catalytic efficiency of PPO conversion. Finally, the cofactor self‐sufficient whole‐cell biocatalyst effectively converted 300 mM PPO to L‐PPT in 2 h without the need to add exogenous cofactors, resulting in a 2.3‐fold increase in PPO conversion (%) from 43% to 100%, with a high space‐time yield of 706.2 g L−1 d−1 and 99.9% ee. Overall, this work demonstrates a technological example for constructing a cofactor self‐sufficient system for NADPH‐dependent redox biocatalysis.

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Section: Introductionmentioning

confidence: 99%

Design of a cofactor self‐sufficient whole‐cell biocatalyst for enzymatic asymmetric reduction via engineered metabolic pathways and multi‐enzyme cascade

Zou,

Zhang,

Han

et al. 2024

Biotechnology Journal

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“…The amination of racemic alcohols to enantiopure amines could be achieved by one-pot cascade reactions consisting of full oxidation of racemic alcohols and enantioselective amination of ketones. The enzyme cascades could combine ADH or AOx, with transaminase (TA), amine dehydrogenase, or amino acid dehydrogenase (AADH), ,,,− ,− but their practical application depends on the enzymes for the full oxidation of racemic alcohols and enantioselective amination, as well as the system for the recycling of the necessary cofactor. We are interested in engineering AOx-MR-TA cascade reactions to convert racemic α-hydroxy acids to enantiopure α-amino acids (Scheme b).…”

Section: Introductionmentioning

confidence: 99%

Engineering of Hydroxymandelate Oxidase and Cascade Reactions for High-Yielding Conversion of Racemic Mandelic Acids to Phenylglyoxylic Acids and (R)- and (S)-Phenylglycines

Jung

2023

ACS Catal.

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An alcohol oxidase (AOx) for the (S)-enantioselective oxidation of 4-hydroxymandelic acid (4-HMA) to 4-hydroxyphenylglyoxylic acid (4-HPGA) with enhanced activity was developed by directed evolution of hydroxymandelate oxidase (HMO) through three rounds of iterative saturation mutagenesis. The engineered HMO mutant A80G-T159S-T162Q (HMOTM) catalyzed the oxidation of (S)-4-HMA to 4-HPGA with a 23-fold enhancement in catalytic efficiency (k cat/K M). Substrate docking simulation on HMOTM suggested that A80G reoriented FMN, while T159S and T162Q formed hydrogen bonds with the carboxylic group of the substrate, thus facilitating substrate binding and catalysis. (S)-Enantioselective HMOTM was used together with mandelic acid racemase (MR) and catalase (KatE) to achieve high-yielding oxidation of rac-4-HMA to 4-HPGA with either purified enzymes (up to 93% yield and 426 mM) or Escherichia coli (HMC) cells expressing the three enzymes (up to 93% yield and 140 mM). The HMOTM-MR-KatE cascades were applied for the oxidation of seven other substituted MAs, producing the corresponding phenylglyoxylic acids with 90–99% conversions using purified enzymes or whole cells. Efficient conversion of racemic α-hydroxy acids to (S)- or (R)-α-amino acids was achieved by combining HMOTM-MR-KatE with (S)-enantioselective transaminase (EcαTA) or (R)-enantioselective transaminase (DpgAT), together with glutamate dehydrogenase (GluDH). Coupling of E. coli (HMC) with E. coli (E-G) expressing EcαTA and GluDH for one-pot biotransformation of five rac-MAs produced the corresponding (S)-phenylglycines (PGs) in 91–99% ee with 73–98% conversions. Using E. coli (HMC) and E. coli (D-G) expressing DpgAT and GluDH enabled the production of five (R)-PGs with 93–99% ee and 73–98% conversions from the corresponding rac-MAs. The engineered AOx, AOx-MR-KatE cascades, and AOx-MR-Kat-GluDH-(S)- or (R)-TA cascades provide useful tools for highly active and enantioselective oxidation of racemic hydroxyacids and high-yielding conversion of racemic hydroxyacids to ketoacids and enantiopure (S)- or (R)-aminoacids, respectively, which are challenging and useful chemical reactions.

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Polyethylene-biodegrading Microbes and Their Future Directions

Seo

Yun

Kim

et al. 2023

Biotechnol Bioproc E

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Improved l-phenylglycine synthesis by introducing an engineered cofactor self-sufficient system

Cited by 6 publications

References 49 publications

Design of a cofactor self‐sufficient whole‐cell biocatalyst for enzymatic asymmetric reduction via engineered metabolic pathways and multi‐enzyme cascade

Design of a cofactor self‐sufficient whole‐cell biocatalyst for enzymatic asymmetric reduction via engineered metabolic pathways and multi‐enzyme cascade

Engineering of Hydroxymandelate Oxidase and Cascade Reactions for High-Yielding Conversion of Racemic Mandelic Acids to Phenylglyoxylic Acids and (R)- and (S)-Phenylglycines

Polyethylene-biodegrading Microbes and Their Future Directions

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