Duangthip Trisrivirat, John M X Hughes, Robin Hoeven, Matthew Faulkner, Helen Toogood, Pimchai Chaiyen, Nigel S Scrutton
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引用次数: 8
Abstract
Successful industrial biotechnological solutions to biofuels and other chemicals production rely on effective competition with existing lower-cost natural sources and synthetic chemistry approaches enabled by adopting low-cost bioreactors and processes. This is achievable by mobilizing Halomonas as a next generation industrial chassis, which can be cultivated under non-sterile conditions. To increase the cost effectiveness of an existing sustainable low carbon bio-propane production strategy, we designed and screened a constitutive promoter library based on the known strong porin promoter from Halomonas. Comparative studies were performed between Escherichia coli and Halomonas using the reporter gene red fluorescent protein (RFP). Later studies with a fatty acid photodecarboxylase-RFP fusion protein demonstrated tuneable propane production in Halomonas and E. coli, with an ∼8-fold improvement in yield over comparable isopropyl-β-D-thiogalactoside-inducible systems. This novel set of promoters is a useful addition to the synthetic biology toolbox for future engineering of Halomonas to make chemicals and fuels.
生物燃料和其他化学品生产的成功工业生物技术解决方案依赖于与现有低成本自然资源和合成化学方法的有效竞争,这些方法通过采用低成本生物反应器和工艺得以实现。这可以通过动员盐单胞菌作为下一代工业底盘来实现,它可以在非无菌条件下培养。为了提高现有可持续低碳生物丙烷生产策略的成本效益,我们基于已知的来自Halomonas的强孔蛋白启动子设计并筛选了一个本构启动子库。利用报告基因红色荧光蛋白(RFP)对大肠杆菌和卤单胞菌进行了比较研究。随后对脂肪酸光脱羧酶- rfp融合蛋白的研究表明,在盐单胞菌和大肠杆菌中可调节丙烷的生产,与类似的异丙基-β- d -硫代半乳糖苷诱导体系相比,产量提高了8倍。这组新颖的启动子是合成生物学工具箱的一个有用的补充,用于未来的盐单胞菌工程,以制造化学品和燃料。
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