Microbial production of high octane and high sensitivity olefinic ester biofuels.

David N Carruthers, Jinho Kim, Daniel Mendez-Perez, Eric Monroe, Nick Myllenbeck, Yuzhong Liu, Ryan W Davis, Eric Sundstrom, Taek Soon Lee
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引用次数: 4

Abstract

Background: Advanced spark ignition engines require high performance fuels with improved resistance to autoignition. Biologically derived olefinic alcohols have arisen as promising blendstock candidates due to favorable octane numbers and synergistic blending characteristics. However, production and downstream separation of these alcohols are limited by their intrinsic toxicity and high aqueous solubility, respectively. Bioproduction of carboxylate esters of alcohols can improve partitioning and reduce toxicity, but in practice has been limited to saturated esters with characteristically low octane sensitivity. If olefinic esters retain the synergistic blending characteristics of their alcohol counterparts, they could improve the bioblendstock combustion performance while also retaining the production advantages of the ester moiety.

Results: Optimization of Escherichia coli isoprenoid pathways has led to high titers of isoprenol and prenol, which are not only excellent standalone biofuel and blend candidates, but also novel targets for esterification. Here, a selection of olefinic esters enhanced blendstock performance according to their degree of unsaturation and branching. E. coli strains harboring optimized mevalonate pathways, thioester pathways, and heterologous alcohol acyltransferases (ATF1, ATF2, and SAAT) were engineered for the bioproduction of four novel olefinic esters. Although prenyl and isoprenyl lactate titers were limited to 1.48 ± 0.41 mg/L and 5.57 ± 1.36 mg/L, strains engineered for prenyl and isoprenyl acetate attained titers of 176.3 ± 16.0 mg/L and 3.08 ± 0.27 g/L, respectively. Furthermore, prenyl acetate (20% bRON = 125.8) and isoprenyl acetate (20% bRON = 108.4) exhibited blend properties comparable to ethanol and significantly better than any saturated ester. By further scaling cultures to a 2-L bioreactor under fed-batch conditions, 15.0 ± 0.9 g/L isoprenyl acetate was achieved on minimal medium. Metabolic engineering of acetate pathway flux further improved titer to attain an unprecedented 28.0 ± 1.0 g/L isoprenyl acetate, accounting for 75.7% theoretical yield from glucose.

Conclusion: Our study demonstrated novel bioproduction of four isoprenoid oxygenates for fuel blending. Our optimized E. coli production strain generated an unprecedented titer of isoprenyl acetate and when paired with its favorable blend properties, may enable rapid scale-up of olefinic alcohol esters for use as a fuel blend additive or as a precursor for longer-chain biofuels and biochemicals.

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微生物生产高辛烷值和高灵敏度烯烃酯生物燃料。
背景:先进的火花点火发动机需要高性能的燃料,提高抗自燃能力。由于良好的辛烷值和协同共混特性,生物衍生的烯烃醇已成为有前途的混合原料。然而,这些醇的生产和下游分离分别受到其固有毒性和高水溶性的限制。醇羧酸酯的生物生产可以改善分配和降低毒性,但在实践中仅限于饱和酯具有低辛烷值敏感性的特征。如果烯烃酯保留其醇类化合物的协同共混特性,则可以在提高生物混合料燃烧性能的同时保留酯部分的生产优势。结果:大肠杆菌类异戊二醇途径的优化得到了高滴度的异戊二醇和丙二醇,它们不仅是优秀的独立生物燃料和混合候选物,而且是酯化的新靶点。在这里,根据烯烃酯的不饱和和分支程度,选择烯烃酯增强了混合料的性能。利用优化的甲羟戊酸途径、硫酯途径和异源醇酰基转移酶(ATF1、ATF2和SAAT)对大肠杆菌菌株进行了改造,用于生产四种新型烯烃酯。虽然乳酸戊烯基和乳酸异戊烯基的滴度限制在1.48±0.41 mg/L和5.57±1.36 mg/L,但为乙酸异戊烯基和丙烯基设计的菌株的滴度分别为176.3±16.0 mg/L和3.08±0.27 g/L。此外,乙酸戊烯酯(20% bRON = 125.8)和乙酸异戊烯酯(20% bRON = 108.4)的共混性能与乙醇相当,明显优于任何饱和酯。在补料条件下,将培养物进一步缩放到2l生物反应器,在最小培养基上达到15.0±0.9 g/L醋酸异戊二酯。乙酸途径通量的代谢工程进一步提高了滴度,达到前所未有的28.0±1.0 g/L乙酸异戊二酯,占葡萄糖理论产率的75.7%。结论:我们的研究证明了用于燃料混合的四种类异戊二烯氧化物的新型生物生产。我们优化的大肠杆菌生产菌株产生了前所未有的醋酸异戊二酯滴度,当与其良好的混合特性配对时,可以快速扩大烯烃醇酯的规模,用作燃料混合添加剂或长链生物燃料和生物化学品的前体。
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