Metabolic engineering of indole pyruvic acid biosynthesis in Escherichia coli with tdiD

Zhu, Yelin; Hua, Yan; Zhang, Biao; Sun, Lianhong; Li, Wenjie; Kong, Xin; Hong, Jiong

doi:10.1186/s12934-016-0620-6

Cited by 5 publications

(4 citation statements)

References 56 publications

(63 reference statements)

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“…Carbohydrate plays an important role in the natural photosynthetic metabolism network of cyanobacteria, and carbohydrate metabolism and transformation is the reaction and material basis of the entire carbon sequestration cycle (Figure 4). Similar to this, Synechococcus elongatus PPC 7942 produced more recombinant protein when the genes responsible for the manufacture of cysteine, another important amino acid, were overexpressed (Zhou et al., 2016).…”

Section: Introductionmentioning

confidence: 85%

Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N₂ gas

Nawaz,

Gu,

Fahad

et al. 2024

Food and Energy Security

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This review explores the potential of genetically engineering cyanobacteria with the aim of synthesizing high‐value protein directly from atmospheric nitrogen. The article examines numerous techniques that may enhance protein synthesis in cyanobacteria, and discusses advantages, barriers, and opportunities for this strategy going forward. Genetic manipulation of cyanobacteria shows promise in sustainably raising protein production via reduced greenhouse gas emissions and lower dependence on synthetic fertilizers, but also potentially fewer environmental implications traditionally caused by conventional protein production methods. The article uncovers many difficulties in genetically modifying cyanobacteria for protein production. For example, genetically modified organisms (GMOs) have legal and regulatory ramifications that must be accounted for if ethical, moral and secure use of these technologies is to be ensured. Economic viability, too, must be evaluated, taking into consideration production costs, scalability, market demand and future market potential. We suggest that processing of cyanobacterial proteins in downstream stages need further development. Effective and economical methods are needed for protein extraction, purification, and formulation into commercially viable products. For successful application of cyanobacterial protein production at scale, such obstacles must be overcome. We conclude that genetic engineering of cyanobacteria for protein synthesis has a great deal of potential to offer a resource‐effective and sustainable replacement for the synthesis of high‐value proteins, so promoting a more sustainable and environmentally conscious future.

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Section: Introductionmentioning

confidence: 85%

Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N₂ gas

Nawaz,

Gu,

Fahad

et al. 2024

Food and Energy Security

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“…3a). The aromatic amino acid transferase from tyrB and aspC were homologs hence the indole-3-pyruvic acid could be produced by aromatic amino acid aminotransferase from tyrB and aspC 30,31 . The puuC showed the highest expression in 3 hrs of time culture (Fig.…”

Section: Discussionmentioning

confidence: 99%

Growth Phase Influence the Gene Expression and Metabolite Production Related to Indole-3-Acetic Acid (IAA) Biosynthesis by Serratia plymuthica UBCF_13

Yusfi¹,

Tjong²,

Chaniago³

et al. 2022

Pakistan J. of Biological Sciences

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Background and Objective: The optimization of the indole-3-acetic acid (IAA) producing capability of Serratia plymuthica UBCF̲13 has been intensively studied. This work tried to reveal the effect of growth phases on IAA production, gene expression and metabolite synthesis related to the IAA biosynthesis pathway. Materials and Methods: The growth curve and IAA production were measured every 3 hrs. The putative IAA biosynthesis pathway was investigated based on the UBCF̲13 genome. To identify the possible pathway of IAA biosynthesis in UBCF̲13, we applied the Quantitative Reverse Transcription Polymerase Chain Reaction (qRT-PCR) and High-Performance Liquid Chromatography (HPLC) analysis to measure the transcript levels of each gene and indole metabolite production based on tryptophan treatment at different times of incubation. Results: The optimal IAA production on colorimetric assay was at 9 hrs of incubation (initial stationary phase). The level expression of puuC, DDC, oxdA, amiE, nthA and nthB have been upregulated maximum in 3 hrs of culture time (lag phase), except tyrB and ipdC. The highest transcript level of the genes was found in nitrile hydratase genes (nthA and nthB) and indole-3-acetamide (IAM) has been detected as the only intermediate in the crude extract of UBCF̲13 thus the IAM pathway may be used to produce IAA. The maximum IAA production on HPLC analysis was found at 21 hrs of incubation (late stationary phase). Conclusion: This study gives a new insight that the best time to measure gene expression and intermediates related to the IAA biosynthetic pathway in bacteria was found at a specific growth phase.

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“…Although part of the l -Trp in BL7992 flowed to the melatonin synthesis pathway, resulting in a down-regulation of the indole, the level of indole (74.6 mg/L) was still fivefold the total concentration of all products in the melatonin synthesis pathway. Tryptophanase encoded by the tnaA gene catalyzes the degradation of l -Trp to indole, ammonium, and pyruvate [ 31 ]. The enzyme can be induced by high concentrations of exogenous l -Trp [ 32 ], leading to a significant accumulation of indole in the culture after the addition of 1 g /L l -Trp as a substrate.…”

Section: Targeted Metabolomics Of L -Trpmentioning

confidence: 99%

Biosynthesis of melatonin from l-tryptophan by an engineered microbial cell factory

Wang,

Deng,

Gao

et al. 2024

Biotechnol Biofuels

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Background The demand for melatonin is increasing due to its health-promoting bioactivities such as antioxidant and sleep benefits. Although melatonin is present in various organisms, its low content and high extraction cost make it unsustainable. Biosynthesis is a promising alternative method for melatonin production. However, the ectopic production of melatonin in microorganisms is very difficult due to the low or insoluble expression of melatonin synthesis genes. Hence, we aim to explore the biosynthesis of melatonin using Escherichia coli as a cell factory and ways to simultaneously coordinated express genes from different melatonin synthesis pathways. Results In this study, the mXcP4H gene from Xanthomonas campestris, as well as the HsAADC, HsAANAT and HIOMT genes from human melatonin synthesis pathway were optimized and introduced into E. coli via a multi-monocistronic vector. The obtained strain BL7992 successfully synthesized 1.13 mg/L melatonin by utilizing L-tryptophan (l-Trp) as a substrate in a shake flask. It was determined that the rate-limiting enzyme for melatonin synthesis is the arylalkylamine N-acetyltransferase, which is encoded by the HsAANAT gene. Targeted metabolomics analysis of l-Trp revealed that the majority of l-Trp flowed to the indole pathway in BL7992, and knockout of the tnaA gene may be beneficial for increasing melatonin production. Conclusions A metabolic engineering approach was adopted and melatonin was successfully synthesized from low-cost l-Trp in E. coli. This study provides a rapid and economical strategy for the synthesis of melatonin.

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Metabolic engineering of indole pyruvic acid biosynthesis in Escherichia coli with tdiD

Cited by 5 publications

References 56 publications

Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N₂ gas

Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N₂ gas

Growth Phase Influence the Gene Expression and Metabolite Production Related to Indole-3-Acetic Acid (IAA) Biosynthesis by Serratia plymuthica UBCF_13

Biosynthesis of melatonin from l-tryptophan by an engineered microbial cell factory

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Metabolic engineering of indole pyruvic acid biosynthesis in Escherichia coli with tdiD

Cited by 5 publications

References 56 publications

Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N2 gas

Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N2 gas

Growth Phase Influence the Gene Expression and Metabolite Production Related to Indole-3-Acetic Acid (IAA) Biosynthesis by Serratia plymuthica UBCF_13

Biosynthesis of melatonin from l-tryptophan by an engineered microbial cell factory

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Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N₂ gas

Sustainable protein production through genetic engineering of cyanobacteria and use of atmospheric N₂ gas