Seamless insert-plasmid assembly at sub-terminal homologous sequences

IF 1.8 4区生物学 Q3 GENETICS & HEREDITY

Plasmid Pub Date : 2019-11-01 DOI:10.1016/j.plasmid.2019.102445

Anna-Sophia Krebs , Tobias Bierig , Gabriella Collu , Roger M. Benoit

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引用次数: 1

Abstract

The engineering of fusion proteins for structural biology and protein nanotechnology often requires seamless DNA assembly with slight variations in the domain boundaries. To improve the molecular biology workflow for such projects, we evaluated the use of sub-terminal homologous sequences (HS) for co-transformation cloning and for T5 exonuclease / Phusion DNA polymerase mediated in vitro assembly. To quantify the effects of different HS-to-ends distances on cloning efficiency, we designed a blue-white-pink screening system that allowed us to easily identify positive clones (blue colonies), negative clones resulting from circular template plasmid (pink colonies) and negative colonies originating from linearized plasmids that have recircularized without an insert (white colonies). Our experiments show that both methods are feasible with HS-to-ends distances up to at least 10 base pairs. Using a combination of co-transformation cloning at sub-terminal HS and nucleotide insertions in non-annealing primer 5′-overhangs, we integrated a fusion protein into the third intracellular loop (ICL) of a G-protein-coupled receptor (GPCR) with nine different linker boundaries, using only a single plasmid linearization reaction. This molecular cloning approach is an invaluable tool for protein engineering, protein nanotechnology and synthetic biology that extends the range of applications of DNA assembly strategies.

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亚末端同源序列的无缝插入-质粒组装

用于结构生物学和蛋白质纳米技术的融合蛋白工程通常需要在结构域边界上略有变化的无缝DNA组装。为了改善这类项目的分子生物学工作流程，我们评估了亚末端同源序列(HS)用于共转化克隆和T5外切酶/融合DNA聚合酶介导的体外组装。为了量化不同HS-to-ends距离对克隆效率的影响，我们设计了一个蓝-白-粉筛选系统，使我们能够轻松地识别阳性克隆(蓝色菌落)，圆形模板质粒产生的阴性克隆(粉色菌落)和来自线性化质粒的阴性菌落，这些质粒在没有插入的情况下再循环(白色菌落)。我们的实验表明，这两种方法都是可行的，hs到末端的距离至少为10个碱基对。利用亚末端HS共转化克隆和非退火引物5 ' -悬垂核苷酸插入相结合的方法，我们仅使用单个质粒线性化反应，将融合蛋白整合到具有9个不同连接体边界的g蛋白偶联受体(GPCR)的第三胞内环(ICL)中。这种分子克隆方法是蛋白质工程、蛋白质纳米技术和合成生物学的宝贵工具，扩展了DNA组装策略的应用范围。

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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来源期刊

Plasmid 生物-遗传学

CiteScore

4.70

自引率

3.80%

发文量

审稿时长

53 days

期刊介绍： Plasmid publishes original research on genetic elements in all kingdoms of life with emphasis on maintenance, transmission and evolution of extrachromosomal elements. Objects of interest include plasmids, bacteriophages, mobile genetic elements, organelle DNA, and genomic and pathogenicity islands.