Iterative cycle of widely targeted metabolic profiling for the improvement of 1-butanol titer and productivity in Synechococcus elongatus

Fathima, Artnice Mega; Chuang, Derrick S.; Laviña, Walter A.; Liao, James C.; Putri, Sastia Prama; Fukusaki, Eiichiro

doi:10.1186/s13068-018-1187-8

Cited by 32 publications

(12 citation statements)

References 38 publications

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“…The engineered cultures were cultivated for a maximum of 30 days, because the cumulative 1-butanol titers had started to drop at day 28, while the cell density started to decrease already from day 12. In this long-term experiment, the authors report a maximum 1-butanol yield of 4.8 g L À1 , which is greater than 10 times higher than the previous record of 0.418 g L À1 , obtained after 6 days of cultivation with engineered Synechococcus elongatus PCC 7942, 6 another model cyanobacterium. Compared to heterotrophic systems, this yield is greater than 5 times higher than the highest yield of 0.835 g L À1 reported for engineered yeast cells.…”

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confidence: 51%

Advances in the Direct Production of Biofuels via Photosynthesis

Hess

2019

Joule

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Photosynthetic cyanobacteria have great promise for the direct production of chemicals and biofuels from CO 2 and water and with sunlight as the sole source of energy. In the current issue of Energy and Environmental Science, Liu et al. present a rigorous modular approach for metabolic engineering. Using Synechocystis PCC 6803 as host and 1-butanol as product, the highest to-date reported rates of biosynthesis from CO 2 are reported. The approach bears substantial potential for the production of many other solar chemicals.

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confidence: 51%

Advances in the Direct Production of Biofuels via Photosynthesis

Hess

2019

Joule

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“…The created strains harboring newly generated promoter sequences with different strength were subjected to metabolome analysis to reveal key metabolites that are most correlated with γ-PGA synthesis. For metabolome analysis according to previous studies (Mitsunaga et al, 2016;Fathima et al, 2018), 93 metabolites were detected that are part of the central carbon metabolism including pentose phosphate pathway (PPP), tricarboxylic acid cycle (TCA), and glycolysis intermediates as well as amino acids and nucleotides. The samples were taken after 8 h during exponential growth.…”

Section: Metabolome Analysis To Reveal Key Metabolitesmentioning

confidence: 99%

Identification of Key Metabolites in Poly-γ-Glutamic Acid Production by Tuning γ-PGA Synthetase Expression

Halmschlag

Putri

Fukusaki

et al. 2020

Front. Bioeng. Biotechnol.

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Poly-γ-glutamic acid (γ-PGA) production is commonly achieved using glycerol, citrate, and L-glutamic acid as substrates. The constitutive expression of the γ-PGA synthetase enabled γ-PGA production with Bacillus subtilis from glucose only. The precursors for γ-PGA synthesis, D-and L-glutamate, are ubiquitous metabolites. Hence, the metabolic flux toward γ-PGA directly depends on the concentration and activity of the synthetase and thereby on its expression. To identify pathway bottlenecks and important metabolites that are highly correlated with γ-PGA production from glucose, we engineered B. subtilis strains with varying γ-PGA synthesis rates. To alter the rate of γ-PGA synthesis, the expression level was controlled by two approaches: (1) Using promoter variants from the constitutive promoter P veg and (2) Varying induction strength of the xylose inducible promoter P xyl . The variation in the metabolism caused by γ-PGA production was investigated using metabolome analysis. The xylose-induction strategy revealed that the γ-PGA production rate increased the total fluxes through metabolism indicating a driven by demand adaption of the metabolism. Metabolic bottlenecks during γ-PGA from glucose were identified by generation of a model that correlates γ-PGA production rate with intracellular metabolite levels. The generated model indicates the correlation of certain metabolites such as phosphoenolpyruvate with γ-PGA production. The identified metabolites are targets for strain improvement to achieve high level γ-PGA production from glucose.

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“…Cyanobacteria is an excellent microbial cell factory that can utilize solar energy and convert atmospheric CO 2 to useful products. Additionally, cyanobacteria can grow rapidly, and its genetic manipulation is easy [62]. Owing to its advantages over heterotrophs, cyanobacteria were equipped with a synthetic pathway of 1-butanol, to produce sustainable and eco-friendly biofuels.…”

Section: Syngasmentioning

confidence: 99%

“…Using metabolomics strategy, Noguchi et al revealed that the reduction reaction of butanoyl-CoA to butanal catalyzed by acylating aldehyde dehydrogenase (PduP) is a possible rate-limiting step in the 1-butanol pathway in Synechococcus elongatus [105]. Therefore, by enhancing the activity of PduP and inserting the gene encoding the subunit of the ACCase from Yarrowia lipolytica into the aldA (encodes for alcohol dehydrogenase) site, S. elongatus recombinant strain DC11 was able to accumulate 418.7 mg/L of 1-butanol, which is almost 1.4-fold more than its parent strain BUOHSE after 6 days of fermentation [62].…”

Section: Engineering Of Rate-limiting Steps In 1-butanol Productionmentioning

confidence: 99%

Genetic engineering of non-native hosts for 1-butanol production and its challenges: a review

Nawab

Wang

et al. 2020

Microb Cell Fact

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Background: Owing to the increase in energy consumption, fossil fuel resources are gradually depleting which has led to the growing environmental concerns; therefore, scientists are being urged to produce sustainable and ecofriendly fuels. Thus, there is a growing interest in the generation of biofuels from renewable energy resources using microbial fermentation. Main text: Butanol is a promising biofuel that can substitute for gasoline; unfortunately, natural microorganisms pose challenges for the economical production of 1-butanol at an industrial scale. The availability of genetic and molecular tools to engineer existing native pathways or create synthetic pathways have made non-native hosts a good choice for the production of 1-butanol from renewable resources. Non-native hosts have several distinct advantages, including using of cost-efficient feedstock, solvent tolerant and reduction of contamination risk. Therefore, engineering non-native hosts to produce biofuels is a promising approach towards achieving sustainability. This paper reviews the currently employed strategies and synthetic biology approaches used to produce 1-butanol in non-native hosts over the past few years. In addition, current challenges faced in using non-native hosts and the possible solutions that can help improve 1-butanol production are also discussed. Conclusion: Non-native organisms have the potential to realize commercial production of 1-butanol from renewable resources. Future research should focus on substrate utilization, cofactor imbalance, and promoter selection to boost 1-butanol production in non-native hosts. Moreover, the application of robust genetic engineering approaches is required for metabolic engineering of microorganisms to make them industrially feasible for 1-butanol production.

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Iterative cycle of widely targeted metabolic profiling for the improvement of 1-butanol titer and productivity in Synechococcus elongatus

Cited by 32 publications

References 38 publications

Advances in the Direct Production of Biofuels via Photosynthesis

Advances in the Direct Production of Biofuels via Photosynthesis

Identification of Key Metabolites in Poly-γ-Glutamic Acid Production by Tuning γ-PGA Synthetase Expression

Genetic engineering of non-native hosts for 1-butanol production and its challenges: a review

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