提高聚羟基烷酸酯生物塑料可持续生产的无细胞原型策略。

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS
Synthetic biology (Oxford, England) Pub Date : 2018-09-04 eCollection Date: 2018-01-01 DOI:10.1093/synbio/ysy016
Richard Kelwick, Luca Ricci, Soo Mei Chee, David Bell, Alexander J Webb, Paul S Freemont
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引用次数: 42

摘要

聚羟基烷酸酯(PHAs)是微生物产生的生物聚合物,可能被用作石油衍生塑料的可持续替代品。然而,pha目前比石油衍生塑料的生产成本更高。因此,需要更有效的生产过程。无细胞代谢工程策略已经被用于优化几种生物合成途径,我们设想无细胞策略可以用于优化pha生物合成途径。为此,我们开发了几种大肠杆菌无细胞系统,用于体外原型化pha生物合成操纵子,以及筛选相关代谢物回收酶。此外,我们通过添加乳清渗透物来定制我们的无细胞反应,乳清渗透物是一种工业废物,以前曾用于优化体内pha的生产。我们发现,加入最佳浓度的乳清渗透物可使相对无细胞GFPmut3b的产量提高约50%。在无细胞转录-翻译原型反应中,气相色谱-质谱定量分析了无细胞3-羟基丁酸盐(3HB)的产生,结果显示所测的Native ΔPhaC_C319A(1.18±0.39µM)、C104 ΔPhaC_C319A(4.62±1.31µM)和C101 ΔPhaC_C319A(2.65±1.27µM) phaCAB操作子的活性存在差异。有趣的是,在体外和体内实验中,最活跃的操纵子C104比原生的phaCAB操纵子产生更高水平的pha(或pha单体)。偶联的无细胞生物转化/转录-翻译反应产生了更高的3HB产率(32.87±6.58µM),这些反应也被用来表征丙酸梭菌乙酰辅酶a循环酶。总之,这些数据表明,无细胞方法补充了体内工作流程,以确定优化pha生产的其他策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Cell-free prototyping strategies for enhancing the sustainable production of polyhydroxyalkanoates bioplastics.

Cell-free prototyping strategies for enhancing the sustainable production of polyhydroxyalkanoates bioplastics.

Cell-free prototyping strategies for enhancing the sustainable production of polyhydroxyalkanoates bioplastics.

Cell-free prototyping strategies for enhancing the sustainable production of polyhydroxyalkanoates bioplastics.

The polyhydroxyalkanoates (PHAs) are microbially-produced biopolymers that could potentially be used as sustainable alternatives to oil-derived plastics. However, PHAs are currently more expensive to produce than oil-derived plastics. Therefore, more efficient production processes would be desirable. Cell-free metabolic engineering strategies have already been used to optimize several biosynthetic pathways and we envisioned that cell-free strategies could be used for optimizing PHAs biosynthetic pathways. To this end, we developed several Escherichia coli cell-free systems for in vitro prototyping PHAs biosynthetic operons, and also for screening relevant metabolite recycling enzymes. Furthermore, we customized our cell-free reactions through the addition of whey permeate, an industrial waste that has been previously used to optimize in vivo PHAs production. We found that the inclusion of an optimal concentration of whey permeate enhanced relative cell-free GFPmut3b production by approximately 50%. In cell-free transcription-translation prototyping reactions, gas chromatography-mass spectrometry quantification of cell-free 3-hydroxybutyrate (3HB) production revealed differences between the activities of the Native ΔPhaC_C319A (1.18 ± 0.39 µM), C104 ΔPhaC_C319A (4.62 ± 1.31 µM) and C101 ΔPhaC_C319A (2.65 ± 1.27 µM) phaCAB operons that were tested. Interestingly, the most active operon, C104 produced higher levels of PHAs (or PHAs monomers) than the Native phaCAB operon in both in vitro and in vivo assays. Coupled cell-free biotransformation/transcription-translation reactions produced greater yields of 3HB (32.87 ± 6.58 µM), and these reactions were also used to characterize a Clostridium propionicum Acetyl-CoA recycling enzyme. Together, these data demonstrate that cell-free approaches complement in vivo workflows for identifying additional strategies for optimizing PHAs production.

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