Systematic Mining and Evaluation of the Sesquiterpene Skeletons as High Energy Aviation Fuel Molecules

Huang, Yanglei; Ye, Ziling; Wan, Xiukun; Ge, Yao; Duan, Jingyu; Li, Jiajia; Yao, Minyu; Sun, Xiang; Deng, Zixin; Shen, Kun; Jiang, Hui; Liu, Tiangang

doi:10.1002/advs.202300889

Cited by 8 publications

(11 citation statements)

References 48 publications

(59 reference statements)

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“…The advancements in synthetic biology and metabolic engineering show significant promise in improving the titer, rate, and yield of target molecules. This potential extends to achieving pathway-dependent theoretical yields using various microbial hosts: Escherichia coli, Pseudomonas putida, Rhodosporidium toruloides, and S. cerevisiae (Kirby et al 2021;Liu et al 2021;Wang et al 2022a;Wang et al 2022b;Huang et al 2023). The majority of reported titers, rates, and yields of terpenes from bench-scale studies (Table A1) are below 5 g/L, 0.15 g/L/h, and 35% of the theoretical yield, primarily utilizing glucose as the sole carbon source.…”

Section: Introductionmentioning

confidence: 98%

Integration of genome-scale metabolic model with biorefinery process model reveals market-competitive carbon-negative sustainable aviation fuel utilizing microbial cell mass lipids and biogenic CO2

Baral,

Banerjee,

Mukhopadhyay

et al. 2024

BioRes

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Producing scalable, economically viable, low-carbon biofuels or biochemicals hinges on more efficient bioconversion processes. While microbial conversion can offer robust solutions, the native microbial growth process often redirects a large fraction of carbon to CO2 and cell mass. By integrating genome-scale metabolic models with techno-economic and life cycle assessment models, this study analyzes the effects of converting cell mass lipids to hydrocarbon fuels, and CO2 to methanol on the facility’s costs and life-cycle carbon footprint. Results show that upgrading microbial lipids or both microbial lipids and CO2 using renewable hydrogen produces carbon-negative bisabolene. Additionally, on-site electrolytic hydrogen production offers a supply of pure oxygen to use in place of air for bioconversion and fuel combustion in the boiler. To reach cost parity with conventional jet fuel, renewable hydrogen needs to be produced at less than $2.2 to $3.1/kg, with a bisabolene yield of 80% of the theoretical yield, along with cell mass and CO2 yields of 22 wt% and 54 wt%, respectively. The economic combination of cell mass, CO2, and bisabolene yields demonstrated in this study provides practical insights for prioritizing research, selecting suitable hosts, and determining necessary engineered production levels.

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Section: Introductionmentioning

confidence: 98%

Integration of genome-scale metabolic model with biorefinery process model reveals market-competitive carbon-negative sustainable aviation fuel utilizing microbial cell mass lipids and biogenic CO2

Baral,

Banerjee,

Mukhopadhyay

et al. 2024

BioRes

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“…Zealexin A1 is a small-molecule secondary metabolite synthesized by plants under biotic or abiotic stress, which is resistant to disease, insects, and drought. , Patchouli essential oil, which is rich in a variety of sesquiterpenes, acts as a fixative in the perfume and cosmetics industry for its long-lasting fragrance and slow volatilization . Other sesquiterpenes, such as α-farnesene and bisabolene, have been identified as promising ingredients for aviation fuels due to their high energy density and combustion heat characteristics . At present, the natural plant extraction and chemical synthesis of sesquiterpenes have the limitations of low yield and high toxicity, which constrain its large-scale production.…”

Section: Introductionmentioning

confidence: 99%

“…5 Other sesquiterpenes, such as α-farnesene and bisabolene, have been identified as promising ingredients for aviation fuels due to their high energy density and combustion heat characteristics. 6 At present, the natural plant extraction and chemical synthesis of sesquiterpenes have the limitations of low yield and high toxicity, which constrain its large-scale production. With the development of metabolic engineering and synthetic biology, heterologous biosynthesis has been applied to produce sesquiterpenes.…”

Section: Introductionmentioning

confidence: 99%

Catalytic Mechanism and Heterologous Biosynthesis Application of Sesquiterpene Synthases

Nie,

Wang,

Chen

et al. 2024

J. Agric. Food Chem.

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Sesquiterpenes comprise a diverse group of natural products with a wide range of applications in cosmetics, food, medicine, agriculture, and biofuels. Heterologous biosynthesis is increasingly employed for sesquiterpene production, aiming to overcome the limitations associated with chemical synthesis and natural extraction. Sesquiterpene synthases (STSs) play a crucial role in the heterologous biosynthesis of sesquiterpene. Under the catalysis of STSs, over 300 skeletons are produced through various cyclization processes (C1-C10 closure, C1-C11 closure, C1-C6 closure, and C1-C7 closure), which are responsible for the diversity of sesquiterpenes. According to the cyclization types, we gave an overview of advances in understanding the mechanism of STSs cyclization from the aspects of protein crystal structures and site-directed mutagenesis. We also summarized the applications of engineering STSs in the heterologous biosynthesis of sesquiterpene. Finally, the bottlenecks and potential research directions related to the STSs cyclization mechanism and application of modified STSs were presented.

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“…17,18 According to studies, approximately 25.5 g/L α-farnesene has been obtained from engineered Y. lipolytica 17 and 38.8 and 10.4 g/L α-farnesene produced by S. cerevisiae. 13,19 In other microorganisms, only low-level α-farnesene production has been reported, such as 2.6 g/L in P. pastoris, 15 1.1 g/L in E. coli, 20 and 13.0 mg/L in Synechococcus elongatus. 21 Despite various effective metabolic engineering strategies used to improve α-farnesene production in various strains, the maximum titer of α-farnesene remains far lower than that of β-farnesene (approximately 130 g/L in engineered S. cerevisiae).…”

Section: ■ Introductionmentioning

confidence: 99%

“…lipolytica and 38.8 and 10.4 g/L α-farnesene produced by S. cerevisiae. , In other microorganisms, only low-level α-farnesene production has been reported, such as 2.6 g/L in P. pastoris, 1.1 g/L in E.…”

Section: Introductionmentioning

confidence: 99%

Enzyme and Metabolic Engineering Strategies for Biosynthesis of α-Farnesene in Saccharomyces cerevisiae

Qiao

Zhan

Nie

et al. 2023

J. Agric. Food Chem.

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α-Farnesene, a type of acyclic sesquiterpene, is an important raw material in agriculture, aircraft fuel, and the chemical industry. In this study, we constructed an efficient α-farnesene-producing yeast cell factory by combining enzyme and metabolic engineering strategies. First, we screened different plants for α-farnesene synthase (AFS) with the best activity and found that AFS from Camellia sinensis (CsAFS) exhibited the most efficient α-farnesene production in Saccharomyces cerevisiae 4741. Second, the metabolic flux of the mevalonate pathway was increased to improve the supply of the precursor farnesyl pyrophosphate. Third, inducing site-directed mutagenesis in CsAFS, the CsAFSW281C variant was obtained, which considerably increased α-farnesene production. Fourth, the N-terminal serine–lysine–isoleucine–lysine (SKIK) tag was introduced to construct the SKIK∼CsAFSW281C variant, which further increased α-farnesene production to 2.8 g/L in shake-flask cultures. Finally, the α-farnesene titer of 28.3 g/L in S. cerevisiae was obtained by fed-batch fermentation in a 5 L bioreactor.

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Systematic Mining and Evaluation of the Sesquiterpene Skeletons as High Energy Aviation Fuel Molecules

Cited by 8 publications

References 48 publications

Integration of genome-scale metabolic model with biorefinery process model reveals market-competitive carbon-negative sustainable aviation fuel utilizing microbial cell mass lipids and biogenic CO2

Integration of genome-scale metabolic model with biorefinery process model reveals market-competitive carbon-negative sustainable aviation fuel utilizing microbial cell mass lipids and biogenic CO2

Catalytic Mechanism and Heterologous Biosynthesis Application of Sesquiterpene Synthases

Enzyme and Metabolic Engineering Strategies for Biosynthesis of α-Farnesene in Saccharomyces cerevisiae

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