Department of Applied Molecular Bioscience, Graduate School of Medicine, Yamaguchi University, Tokiwadai, Ube, Japan.
Yeast. 2014 Jan;31(1):29-46. doi: 10.1002/yea.2993. Epub 2013 Dec 19.
The cloning of DNA fragments into vectors or host genomes has traditionally been performed using Escherichia coli with restriction enzymes and DNA ligase or homologous recombination-based reactions. We report here a novel DNA cloning method that does not require DNA end processing or homologous recombination, but that ensures highly accurate cloning. The method exploits the efficient non-homologous end-joining (NHEJ) activity of the yeast Kluyveromyces marxianus and consists of a novel functional marker selection system. First, to demonstrate the applicability of NHEJ to DNA cloning, a C-terminal-truncated non-functional ura3 selection marker and the truncated region were PCR-amplified separately, mixed and directly used for the transformation. URA3(+) transformants appeared on the selection plates, indicating that the two DNA fragments were correctly joined by NHEJ to generate a functional URA3 gene that had inserted into the yeast chromosome. To develop the cloning system, the shortest URA3 C-terminal encoding sequence that could restore the function of a truncated non-functional ura3 was determined by deletion analysis, and was included in the primers to amplify target DNAs for cloning. Transformation with PCR-amplified target DNAs and C-terminal truncated ura3 produced numerous transformant colonies, in which a functional URA3 gene was generated and was integrated into the chromosome with the target DNAs. Several K. marxianus circular plasmids with different selection markers were also developed for NHEJ-based cloning and recombinant DNA construction. The one-step DNA cloning method developed here is a relatively simple and reliable procedure among the DNA cloning systems developed to date.
传统的 DNA 片段克隆到载体或宿主基因组中,是使用大肠杆菌和限制性内切酶和 DNA 连接酶,或者基于同源重组的反应来完成的。我们在这里报告一种新的 DNA 克隆方法,它不需要 DNA 末端处理或同源重组,但能确保高度准确的克隆。该方法利用了酿酒酵母 Kluyveromyces marxianus 的高效非同源末端连接(NHEJ)活性,并包含一个新的功能标记选择系统。首先,为了证明 NHEJ 可应用于 DNA 克隆,我们分别扩增了 C 端截断的非功能 ura3 选择标记和截断区域,然后将它们混合并直接用于转化。URA3(+)转化体出现在选择平板上,表明这两个 DNA 片段通过 NHEJ 正确连接,生成了一个插入酵母染色体的功能性 URA3 基因。为了开发克隆系统,我们通过缺失分析确定了可以恢复截断非功能 ura3 的最短 C 端编码序列,并将其包含在用于克隆的目标 DNA 的引物中。用 PCR 扩增的目标 DNA 和 C 端截断 ura3 转化,产生了大量的转化体菌落,其中生成了功能性 URA3 基因,并与目标 DNA 一起整合到染色体中。还开发了几种带有不同选择标记的 K. marxianus 环状质粒,用于基于 NHEJ 的克隆和重组 DNA 构建。这里开发的一步法 DNA 克隆方法是迄今为止开发的 DNA 克隆系统中相对简单和可靠的程序。
