Renewable synthesis of n-butyraldehyde from glucose by engineered Escherichia coli

Ku, Jason T.; Simanjuntak, Wiwik; Lan, Ethan I.

doi:10.1186/s13068-017-0978-7

Cited by 26 publications

(25 citation statements)

References 28 publications

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“…Chemical feedstock BW25113 630 mg/L Expression of mono-functional aldehyde dehydrogenase instead of the conventional bi-functional aldehyde/alcohol dehydrogenase (Ku et al, 2017).…”

Section: Butyraldehydementioning

confidence: 99%

“…Intermediates of the Clostridial pathway have also been produced. The synthesis of butyraldehyde was achieved through replacing the bifunctional alcohol aldehyde dehydrogenase in the butanol pathway with a mono-functional aldehyde dehydrogenase (Ku et al, 2017). Butyraldehyde serves as a precursor to biological propane production (Kallio et al, 2014).…”

Section: Biofuelsmentioning

confidence: 99%

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Escherichia coli as a host for metabolic engineering

Pontrelli

Chiu

Lan

et al. 2018

Metabolic Engineering

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278

140

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Over the past century, Escherichia coli has become one of the best studied organisms on earth. Features such as genetic tractability, favorable growth conditions, well characterized biochemistry and physiology, and availability of versatile genetic manipulation tools make E. coli an ideal platform host for development of industrially viable productions. In this review, we discuss the physiological attributes of E. coli that are most relevant for metabolic engineering, as well as emerging techniques that enable efficient phenotype construction. Further, we summarize the large number of native and non-native products that have been synthesized by E. coli, and address some of the future challenges in broadening substrate range and fighting phage infection.

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“…Chemical feedstock BW25113 630 mg/L Expression of mono-functional aldehyde dehydrogenase instead of the conventional bi-functional aldehyde/alcohol dehydrogenase (Ku et al, 2017).…”

Section: Butyraldehydementioning

confidence: 99%

Section: Biofuelsmentioning

confidence: 99%

Escherichia coli as a host for metabolic engineering

Pontrelli

Chiu

Lan

et al. 2018

Metabolic Engineering

Self Cite

278

140

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“…Subsequently, butyryl‐CoA is converted to butyrate via butyryl‐phosphate. A synthetic chain elongation pathway extending acetyl‐CoA to butyryl‐CoA has been developed for efficient butanol (Bond‐Watts, Bellerose, & Chang, ; Shen et al, ) and butyraldehyde (Ku, Simanjuntak, & Lan, ) biosynthesis. However, we previously identified that thiolase, catalyzing the Claisen condensation of two acetyl‐CoA, is a major limiting step for cyanobacterial butanol production.…”

Section: Introductionmentioning

confidence: 99%

Photoautotrophic synthesis of butyrate by metabolically engineered cyanobacteria

Lai

Lan

2019

Biotech & Bioengineering

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Direct conversion of carbon dioxide into chemicals using engineered autotrophic microorganisms offers a potential solution for both sustainability and carbon mitigation.Butyrate is an important chemical used in various industries, including fragrance, food, and plastics. A model cyanobacterium Synechococcus elongatus PCC 7942 was engineered for the direct photosynthetic conversion of CO 2 to butyrate. An engineered Clostridium Coenzyme A (CoA)-dependent pathway leading to the synthesis of butyryl-CoA, the precursor to butyrate, was introduced into S. elongatus PCC 7942. Two CoA removal strategies were then individually coupled to the modified CoA-dependent pathway to yield butyrate production. Similar results were observed between the two CoA removal strategies. The best butyrate producing strain of S. elongatus resulted in an observed butyrate titer of 750 mg/L and a cumulative titer of 1.1 g/L. These results demonstrated the feasibility of photosynthetic butyrate production and expanded the chemical repertoire accessible for production by photoautotrophs. K E Y W O R D Sbutyrate kinase, butyric acid, cyanobacteria, metabolic engineering, phosphotransbutyrylase, thioesterase

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“…[114d, 186] An ethoxylated version of 6d (EO-6d)w as pre-pared by allowing the growth of short oligo(ethylene oxide) chains on each hydroxy group of 6d followed by capping with ECH and carbonation. [187] As the latter aldehydes can be derived from bio-alcohols or from the fermentation of glucose, [188] 6d and 6e can be regarded as potentially renewable carbonates. [184] Trimethylolpropane and pentaerythritol, used as reagents for the synthesis of 6d and 6e,respectively,can be prepared by the reactions of formaldehyde with n-butyraldehyde or acetaldehyde.…”

Section: Monomers With Multiple 5cc Moietiesmentioning

confidence: 99%

“…[184] Trimethylolpropane and pentaerythritol, used as reagents for the synthesis of 6d and 6e,respectively,can be prepared by the reactions of formaldehyde with n-butyraldehyde or acetaldehyde. [187] As the latter aldehydes can be derived from bio-alcohols or from the fermentation of glucose, [188] 6d and 6e can be regarded as potentially renewable carbonates. 6f can be prepared from glycerol and ECH.…”

Section: Monomers With Multiple 5cc Moietiesmentioning

confidence: 99%

Polymers Based on Cyclic Carbonates as Trait d'Union Between Polymer Chemistry and Sustainable CO₂ Utilization

et al. 2019

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Given the large amount of anthropogenic CO2 emissions, it is advantageous to use CO2 as feedstock for the fabrication of everyday products, such as fuels and materials. An attractive way to use CO2 in the synthesis of polymers is by the formation of five‐membered cyclic organic carbonate monomers (5CCs). The sustainability of this synthetic approach is increased by using scaffolds prepared from renewable resources. Indeed, recent years have seen the rise of various types of carbonate syntheses and applications. 5CC monomers are often polymerized with diamines to yield polyhydroxyurethanes (PHU). Foams are developed from this type of polymers; moreover, the additional hydroxyl groups in PHU, absent in classical polyurethanes, lead to coatings with excellent adhesive properties. Furthermore, carbonate groups in polymers offer the possibility of post‐functionalization, such as curing reactions under mild conditions. Finally, the polarity of carbonate groups is remarkably high, so polymers with carbonates side‐chains can be used as polymer electrolytes in batteries or as conductive membranes. The target of this Review is to highlight the multiple opportunities offered by polymers prepared from and/or containing 5CCs. Firstly, the preparation of several classes of 5CCs is discussed with special focus on the sustainability of the synthetic routes. Thereafter, specific classes of polymers are discussed for which the use and/or presence of carbonate moieties is crucial to impart the targeted properties (foams, adhesives, polymers for energy applications, and other functional materials).

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Renewable synthesis of n-butyraldehyde from glucose by engineered Escherichia coli

Cited by 26 publications

References 28 publications

Escherichia coli as a host for metabolic engineering

Escherichia coli as a host for metabolic engineering

Photoautotrophic synthesis of butyrate by metabolically engineered cyanobacteria

Polymers Based on Cyclic Carbonates as Trait d'Union Between Polymer Chemistry and Sustainable CO₂ Utilization

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Renewable synthesis of n-butyraldehyde from glucose by engineered Escherichia coli

Cited by 26 publications

References 28 publications

Escherichia coli as a host for metabolic engineering

Escherichia coli as a host for metabolic engineering

Photoautotrophic synthesis of butyrate by metabolically engineered cyanobacteria

Polymers Based on Cyclic Carbonates as Trait d'Union Between Polymer Chemistry and Sustainable CO2 Utilization

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Product

Resources

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Polymers Based on Cyclic Carbonates as Trait d'Union Between Polymer Chemistry and Sustainable CO₂ Utilization