Production of fatty acid-derived oleochemicals and biofuels by synthetic yeast cell factories

Zhou, Yongjin J.; Buijs, Nicolaas A.; Zhu, Zhiwei; Qin, Jiufu; Siewers, Verena; Nielsen, Jens

doi:10.1038/ncomms11709

Cited by 326 publications

(339 citation statements)

References 54 publications

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“…A range of enzymes and pathways have been heterologously expressed to convert fatty acid thioesters-produced by endogenous fatty acid biosynthesis-into ethyl esters, acids, alcohols, alkanes, methyl ketones, dicarboxylic acids, etc. (Clomburg et al, 2015;Goh et al, 2012;Zhou et al, 2016). Among these products, long-chain fatty alcohols in the C12-C18 range have recently received intense attention due to their value and broad applications in laundry detergents, industrial lubricants and surfactants, medicines and personal care products, and potentially as biofuels (Feng et al, 2015;Liu et al, 2016;Pfleger et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Engineering high-level production of fatty alcohols by Saccharomyces cerevisiae from lignocellulosic feedstocks

d’Espaux

Ghosh

Runguphan

et al. 2017

Metabolic Engineering

103

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A B S T R A C TFatty alcohols in the C12-C18 range are used in personal care products, lubricants, and potentially biofuels. These compounds can be produced from the fatty acid pathway by a fatty acid reductase (FAR), yet yields from the preferred industrial host Saccharomyces cerevisiae remain under 2% of the theoretical maximum from glucose. Here we improved titer and yield of fatty alcohols using an approach involving quantitative analysis of protein levels and metabolic flux, engineering enzyme level and localization, pull-push-block engineering of carbon flux, and cofactor balancing. We compared four heterologous FARs, finding highest activity and endoplasmic reticulum localization from a Mus musculus FAR. After screening an additional twenty-one single-gene edits, we identified increasing FAR expression; deleting competing reactions encoded by DGA1, HFD1, and ADH6; overexpressing a mutant acetyl-CoA carboxylase; limiting NADPH and carbon usage by the glutamate dehydrogenase encoded by GDH1; and overexpressing the Δ9-desaturase encoded by OLE1 as successful strategies to improve titer. Our final strain produced 1.2 g/L fatty alcohols in shake flasks, and 6.0 g/L in fed-batch fermentation, corresponding to~20% of the maximum theoretical yield from glucose, the highest titers and yields reported to date in S. cerevisiae. We further demonstrate high-level production from lignocellulosic feedstocks derived from ionic-liquid treated switchgrass and sorghum, reaching 0.7 g/L in shake flasks. Altogether, our work represents progress towards efficient and renewable microbial production of fatty acidderived products.

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Section: Introductionmentioning

confidence: 99%

Engineering high-level production of fatty alcohols by Saccharomyces cerevisiae from lignocellulosic feedstocks

d’Espaux

Ghosh

Runguphan

et al. 2017

Metabolic Engineering

103

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“…Yarrowia lipolytica is a well-studied oleaginous organism and extensively used for industrial biofuel production, and it has been served as a model organism for biofuel research, especially for fatty acid-derived fuels (Beopoulos et al, 2009;Tai and Stephanopoulos, 2013;Blazeck et al, 2014;Zhou et al, 2016). Several metabolic engineering tools are available for Y. lipolytica (Juretzek et al, 2001;Madzak, 2015).…”

Section: Y Lipolytica Cell Factory For Biofuel Productionmentioning

confidence: 99%

Synthetic Biology and Metabolic Engineering Approaches and Its Impact on Non-Conventional Yeast and Biofuel Production

et al. 2017

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The increasing fossil fuel scarcity has led to an urgent need to develop alternative fuels. Currently microorganisms have been extensively used for the production of first-generation biofuels from lignocellulosic biomass. Yeast is the efficient producer of bioethanol among all existing biofuels option. Tools of synthetic biology have revolutionized the field of microbial cell factories especially in the case of ethanol and fatty acid production. Most of the synthetic biology tools have been developed for the industrial workhorse Saccharomyces cerevisiae. The non-conventional yeast systems have several beneficial traits like ethanol tolerance, thermotolerance, inhibitor tolerance, genetic diversity, etc., and synthetic biology have the power to expand these traits. Currently, synthetic biology is slowly widening to the non-conventional yeasts like Hansenula polymorpha, Kluyveromyces lactis, Pichia pastoris, and Yarrowia lipolytica. Herein, we review the basic synthetic biology tools that can apply to non-conventional yeasts. Furthermore, we discuss the recent advances employed to develop efficient biofuel-producing non-conventional yeast strains by metabolic engineering and synthetic biology with recent examples. Looking forward, future synthetic engineering tools' development and application should focus on unexplored non-conventional yeast species.

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“…[69] S. cerevisiae FAEE, fatty acid short-and branched-chain alkyl esters 230 mg L À1 Batch, 72 h Deletion of Rpd3 and Opi1 with targeted mitochondrial expression of five isobutanol pathway enzymes (Ilv2, Ilv5, Ilv3, Aro10, and Adh7) [75] Y. lipolytica FAEE 142.53 mg L À1 Batch, 90 h ER-targeted expression of Acinetobacter baylyi wax-ester synthase, AbAtfA, and overexpression of a peroxisomal/mitochondrial carnitine acyltransferase, perCat2 [83] Alkanes E. coli Short chain alkanes 0.5 g L À1 Fed-batch a) Deletion of fadR; expression of a modified thioesterase from E. coli [71] E. coli Long chain alkanes 1.3 g L À1 Fed-batch, 40.5 h Modular transcriptional regulation of fatty acid biosynthesis, lipid degradation, and electron transport chain genes. [86] S. cerevisiae Alkanes 0.8 mg L À1 Fed-batch, 72 h Hfd1, pox1, and adh5 deletion with expression of MmCAR [78] Y. lipolytica Alkanes 23 mg L À1 Batch a) Cytosolic expression of Mycobacterium marinum carboxylic acid reductase MmCAR along with an ACP activation module, BsuSfp [95] (Continued)…”

Section: G L à1mentioning

confidence: 99%

“…[77] A higher titer of fatty acids (1.0 g L À1 ) was reported in plasmid-free S. cerevisiae via accumulating fatty acids and blocking fatty acid activation by deleting two fatty acyl-CoA synthetases (FAA1 and FAA4). [78] Shorter chain fatty acids were also produced in S. cerevisiae by facilitating premature cleavage of shorter fatty acid chains. [79] Pathway optimization and partial disruption of the b-oxidation pathway led to 119 mg L À1 of C 6 -C 10 fatty acids production in S. cerevisiae.…”

Section: Fatty Acidsmentioning

confidence: 99%

“…In S. cerevisiae, 1.5 g L À1 fatty alcohol production was reported by directly converting free fatty acids into fatty aldehydes using a carboxylic acid reductase from Mycobacterium marinum (MmCAR). [78] In addition, the cytoplasmic acetyl-CoA supply was increased by heterologous expression of chimeric citrate lyase pathway enzymes.…”

Section: Fatty Alcohols and Alkyl Estersmentioning

confidence: 99%

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Metabolic Engineering for Advanced Biofuels Production and Recent Advances Toward Commercialization

Meadows

Kang

Lee

2017

Biotechnology Journal

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Research on renewable biofuels produced by microorganisms has enjoyed considerable advances in academic and industrial settings. As the renewable ethanol market approaches maturity, the demand is rising for the commercialization of more energy-dense fuel targets. Many strategies implemented in recent years have considerably increased the diversity and number of fuel targets that can be produced by microorganisms. Moreover, strain optimization for some of these fuel targets has ultimately led to their production at industrial scale. In this review, the recent metabolic engineering approaches for augmenting biofuel production derived from alcohols, isoprenoids, and fatty acids in several microorganisms are discussed. In addition, the successful commercialization ventures for each class of biofuel targets are discussed.

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Production of fatty acid-derived oleochemicals and biofuels by synthetic yeast cell factories

Cited by 326 publications

References 54 publications

Engineering high-level production of fatty alcohols by Saccharomyces cerevisiae from lignocellulosic feedstocks

Engineering high-level production of fatty alcohols by Saccharomyces cerevisiae from lignocellulosic feedstocks

Synthetic Biology and Metabolic Engineering Approaches and Its Impact on Non-Conventional Yeast and Biofuel Production

Metabolic Engineering for Advanced Biofuels Production and Recent Advances Toward Commercialization

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