Redox cofactor engineering in industrial microorganisms: strategies, recent applications and future directions

Jia-heng, Liu; Li, Huiling; Zhao, Guang‐Rong; Caiyin, Qinggele; Qiao, Jianjun

doi:10.1007/s10295-018-2031-7

Cited by 67 publications

(41 citation statements)

References 147 publications

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“…We speculated that the problematic imbalance of NADH/NAD + ratio might be a limiting factor that restricted further improvement of l ‐threonine production. One possible strategy for resolving this issue was to introduce an extra NADH regeneration pathway (J. Liu, Li, Zhao, Caiyin, & Qiao, ). NAD + ‐dependent FDH, catalyzing formate oxidation with conversion of NAD + to NADH, has been widely used for to increase NADH availability in metabolic engineering due to its proven effectiveness and innocuous product (carbon dioxide; Balzer, Thakker, Bennett, & San, ; H. S. Song et al, ; M. Wang, Wang, Zhang, Fan, & Tan, ).…”

Section: Resultsmentioning

confidence: 99%

Two‐stage carbon distribution and cofactor generation for improving l‐threonine production of Escherichia coli

Liu

Xiong

et al. 2018

Biotech & Bioengineering

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L-Threonine, a kind of essential amino acid, has numerous applications in food, pharmaceutical, and aquaculture industries. Fermentative L-threonine production from glucose has been achieved in Escherichia coli. However, there are still several limiting factors hindering further improvement of L-threonine productivity, such as the conflict between cell growth and production, byproduct accumulation, and insufficient availability of cofactors (adenosine triphosphate, NADH, and NADPH).Here, a metabolic modification strategy of two-stage carbon distribution and cofactor generation was proposed to address the above challenges in E. coli THRD, an L-threonine producing strain. The glycolytic fluxes towards tricarboxylic acid cycle were increased in growth stage through heterologous expression of pyruvate carboxylase, phosphoenolpyruvate carboxykinase, and citrate synthase, leading to improved glucose utilization and growth performance. In the production stage, the carbon flux was redirected into L-threonine synthetic pathway via a synthetic genetic circuit. Meanwhile, to sustain the transaminase reaction for L-threonine production, we developed an L-glutamate and NADPH generation system through overexpression of glutamate dehydrogenase, formate dehydrogenase, and pyridine nucleotide transhydrogenase. This strategy not only exhibited 2.02-and 1.21-fold increase in L-threonine production in shake flask and bioreactor fermentation, respectively, but had potential to be applied in the production of many other desired oxaloacetate derivatives, especially those involving cofactor reactions. K E Y W O R D Scarbon distribution, cofactor generation, Escherichia coli, L-threonine, metabolic engineering

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Section: Resultsmentioning

confidence: 99%

Two‐stage carbon distribution and cofactor generation for improving l‐threonine production of Escherichia coli

Liu

Xiong

et al. 2018

Biotech & Bioengineering

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“…Traditional UV mutagenesis is a mature technique that induces a high mutation rate into the receptor strains. Engineering the ribo avin biosynthesis by increasing the supplement of the precursor to the avin coenzyme formation is an e cient pathway that could indirectly activate the secondary metabolite biosynthesis [38][39][40][41]. This cofactor engineering type method has been well utilized in another marine actinomycete [44].…”

Section: Discussionmentioning

confidence: 99%

“…Further enhancement of CRM A production by optimizing intracellular ribo avin supplement Enhancing the cofactor level by engineering its biosynthetic process could drive metabolic ux to improve the biosynthesis of target metabolites [38]. This new metabolic engineering strategy named as cofactor engineering has been well applied to microbial second metabolites development [39][40][41]. Previous study had revealed that the biosynthesis of CRM A required several essential avoenzymes, including CamD, which completed the formation of the picolinic acid precursor; CamH, which catalyzed the formation of the oxime group, and CamK, which maintained the substrate recycling process [23,28,29].…”

Section: Enhancement Of Crm a Production By Uv Mutagenesismentioning

confidence: 99%

Activation and enhancement of Caerulomycin A biosynthesis in marine-derived Actinoalloteichus sp. AHMU CJ021 by combinatorial genome mining strategies

Xie

Chen

Wang

et al. 2020

Preprint

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Backgrounds: Activation of silent biosynthetic gene clusters (BGCs) in marine-derived actinomycete strains is a feasible strategy to discover bioactive natural products. Actinoalloteichus sp. AHMU CJ021, isolated from the seashore, was shown to contain an intact but silent caerulomycin A (CRM A) BGC- cam in its genome. Thus, a genome mining work was preformed to activate the strain’s production of CRM A, an immunosuppressive drug lead with diverse bioactivities.Results: To well activate the expression of cam , ribosome engineering was adopted to treat the wild type Actinoalloteichus sp. AHMU CJ021. The initial mutant strain XC-11G with gentamycin resistance and CRM A production titer of 42.51 ± 4.22 mg/L was selected from all generated mutant strains by gene expression comparison of the essential biosynthetic gene-camE. The titer of CRM A production was then improved by two strain breeding methods via UV mutagenesis and cofactor engineering-directed increase of intracellular riboflavin, which finally generated the optimal mutant strain XC-11GUR with a CRM A production titer of 113.91 ± 7.58 mg/L. Subsequently, this titer of strain XC-11GUR was improved to 618.61 ± 16.29 mg/L through medium optimization together with further adjustment derived from response surface methodology. In terms of this 14.6 folds increase in the titer of CRM A compared to the initial value, strain XC-GUR could be a well alternative strain for CRM A development.Conclusions: Our results have constructed an ideal CRM A producer. More importantly, our efforts also have demonstrated the effectiveness of abovementioned combinatorial strategies, which is applicable to the genome mining of bioactive natural products from abundant actinomycetes strains.

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“…In order to further increase the production of 3β-O-Glc-DM and 20S-O-Glc-DM, the cofactor engineering strategies can be used for solving the problematic redox imbalance in metabolic modification in the future. 41,42 Production of 3β-O-Glc-DM and 20S-O-Glc-DM through fed-batch fermentation In order to achieve higher production of 3β-O-Glc-DM and 20S-O-Glc-DM, we chose the engineered strains Y1CSH and Y2CSH for fed-batch fermentation which was performed in a 3 L bioreactor with the pH controlled at 5.5. As shown in Fig.…”

Section: Effect Of Overexpressing Of Chaperone and Transcriptional Acmentioning

confidence: 99%

Construction and optimization of microbial cell factories for sustainable production of bioactive dammarenediol-II glucosides

Liang

et al. 2019

Green Chem.

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Redox cofactor engineering in industrial microorganisms: strategies, recent applications and future directions

Cited by 67 publications

References 147 publications

Two‐stage carbon distribution and cofactor generation for improving l‐threonine production of Escherichia coli

Two‐stage carbon distribution and cofactor generation for improving l‐threonine production of Escherichia coli

Activation and enhancement of Caerulomycin A biosynthesis in marine-derived Actinoalloteichus sp. AHMU CJ021 by combinatorial genome mining strategies

Construction and optimization of microbial cell factories for sustainable production of bioactive dammarenediol-II glucosides

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