使用块推拉方法重新连接大肠杆菌裂解物中的无细胞代谢通量。

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS Synthetic biology (Oxford, England) Pub Date : 2023-04-17 eCollection Date: 2023-01-01 DOI:10.1093/synbio/ysad007
Jaime Lorenzo N Dinglasan, Mitchel J Doktycz
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引用次数: 1

摘要

无细胞系统可以绕过与使用活细胞相关的麻烦要求,加快生物制造工艺的设计和实施。特别是,缺乏生存目标和无细胞反应的开放性提供了允许有目的地指导代谢通量的工程方法。与基于细胞的对应物相比,使用基于裂解物的系统来生产所需的小分子可以产生具有竞争力的滴度和生产力。然而,内源性裂解物代谢中的通路串扰会通过将碳流从所需产物中转移出来而影响转化率。在这里,传统的基于细胞的代谢工程的“块-推-拉”概念被用于开发一种无细胞方法,该方法有效地引导裂解物中的碳从葡萄糖流向内源性乙醇合成。该方法易于适应,相对快速,并允许操纵细胞提取物中的中枢代谢。在实施这种方法时,首先优化阻断策略,使酶能够从裂解物中选择性去除,达到消除副产物形成活性的程度,同时引导通量通过靶通路。这与无细胞代谢工程方法相补充,该方法操纵裂解物蛋白质组和反应环境,以突破瓶颈并将流量拉向乙醇。结合这些阻断、推拉策略的方法最大限度地提高了最初具有低乙醇生成潜力的大肠杆菌裂解物中葡萄糖到乙醇的转化率。百分产率提高了10倍。据我们所知,这是第一份在没有源菌株优化的情况下成功地重新布线裂解物碳通量的报告,并在基于裂解物的无细胞系统中将消耗的输入底物完全转化为所需的输出产物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Rewiring cell-free metabolic flux in E. coli lysates using a block-push-pull approach.

Cell-free systems can expedite the design and implementation of biomanufacturing processes by bypassing troublesome requirements associated with the use of live cells. In particular, the lack of survival objectives and the open nature of cell-free reactions afford engineering approaches that allow purposeful direction of metabolic flux. The use of lysate-based systems to produce desired small molecules can result in competitive titers and productivities when compared to their cell-based counterparts. However, pathway crosstalk within endogenous lysate metabolism can compromise conversion yields by diverting carbon flow away from desired products. Here, the 'block-push-pull' concept of conventional cell-based metabolic engineering was adapted to develop a cell-free approach that efficiently directs carbon flow in lysates from glucose and toward endogenous ethanol synthesis. The approach is readily adaptable, is relatively rapid and allows for the manipulation of central metabolism in cell extracts. In implementing this approach, a block strategy is first optimized, enabling selective enzyme removal from the lysate to the point of eliminating by-product-forming activity while channeling flux through the target pathway. This is complemented with cell-free metabolic engineering methods that manipulate the lysate proteome and reaction environment to push through bottlenecks and pull flux toward ethanol. The approach incorporating these block, push and pull strategies maximized the glucose-to-ethanol conversion in an Escherichia coli lysate that initially had low ethanologenic potential. A 10-fold improvement in the percent yield is demonstrated. To our knowledge, this is the first report of successfully rewiring lysate carbon flux without source strain optimization and completely transforming the consumed input substrate to a desired output product in a lysate-based, cell-free system.

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