模块化无细胞表达质粒,加速细胞中的生物设计。

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS
Synthetic biology (Oxford, England) Pub Date : 2020-10-14 eCollection Date: 2020-01-01 DOI:10.1093/synbio/ysaa019
Ashty S Karim, Fungmin Eric Liew, Shivani Garg, Bastian Vögeli, Blake J Rasor, Aislinn Gonnot, Marilene Pavan, Alex Juminaga, Séan D Simpson, Michael Köpke, Michael C Jewett
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引用次数: 0

摘要

工业生物技术旨在利用可再生资源生产高价值产品。这可能具有挑战性,因为模式微生物(大肠杆菌等易于使用的微生物)往往缺乏利用木质纤维素生物质或合成气等理想原料所需的机制。梭状芽孢杆菌等非模式生物已在工业上得到验证,具有理想的新陈代谢功能,但在主流应用方面存在一些障碍。也就是说,与传统的实验室微生物相比,这些物种的生长速度更慢,而且对其进行工程改造的基因工具也远未普及。为了克服这些障碍,加速细胞设计,无细胞合成生物学已经发展成熟,成为表征非模式生物和快速测试体外代谢途径的一种方法。遗憾的是,无细胞系统可能需要专门的 DNA 架构,其最小调控与细胞表达不兼容。在这项工作中,我们开发了一种模块化载体系统,可以用 T7 表达所需的酶,进行无细胞表达,并直接将 Golden Gate 组装到梭菌表达载体中。利用联合基因组研究所的 DNA 合成社区科学计划,我们设计并合成了这些质粒和项目所需的基因,使我们能够在体外和体内实验之间轻松穿梭 DNA。接下来,我们验证了这些载体足以在无细胞条件下表达功能性酶,其性能与之前最先进的载体相当。最后,我们展示了用于自乙烷梭菌表达的六部分 DNA 自动组装,效率在 68% 到 90% 之间。我们预计这一质粒系统将缩短开发周期,从而为体外和体内生物合成途径的便捷测试提供一个框架。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modular cell-free expression plasmids to accelerate biological design in cells.

Industrial biotechnology aims to produce high-value products from renewable resources. This can be challenging because model microorganisms-organisms that are easy to use like Escherichia coli-often lack the machinery required to utilize desired feedstocks like lignocellulosic biomass or syngas. Non-model organisms, such as Clostridium, are industrially proven and have desirable metabolic features but have several hurdles to mainstream use. Namely, these species grow more slowly than conventional laboratory microbes, and genetic tools for engineering them are far less prevalent. To address these hurdles for accelerating cellular design, cell-free synthetic biology has matured as an approach for characterizing non-model organisms and rapidly testing metabolic pathways in vitro. Unfortunately, cell-free systems can require specialized DNA architectures with minimal regulation that are not compatible with cellular expression. In this work, we develop a modular vector system that allows for T7 expression of desired enzymes for cell-free expression and direct Golden Gate assembly into Clostridium expression vectors. Utilizing the Joint Genome Institute's DNA Synthesis Community Science Program, we designed and synthesized these plasmids and genes required for our projects allowing us to shuttle DNA easily between our in vitro and in vivo experiments. We next validated that these vectors were sufficient for cell-free expression of functional enzymes, performing on par with the previous state-of-the-art. Lastly, we demonstrated automated six-part DNA assemblies for Clostridium autoethanogenum expression with efficiencies ranging from 68% to 90%. We anticipate this system of plasmids will enable a framework for facile testing of biosynthetic pathways in vitro and in vivo by shortening development cycles.

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