Messerschmidt Katrin, Hochrein Lena, Dehm Daniel, Schulz Karina, Mueller-Roeber Bernd
University of Potsdam, Cell2Fab Research Unit, Karl-Liebknecht-Str. 24-25, 14476 Potsdam, Germany.
University of Potsdam, Cell2Fab Research Unit, Karl-Liebknecht-Str. 24-25, 14476 Potsdam, Germany.
Anal Biochem. 2016 Sep 15;509:24-32. doi: 10.1016/j.ab.2016.05.029. Epub 2016 Jun 14.
Synthetic biology aims at designing and engineering organisms. The engineering process typically requires the establishment of suitable DNA constructs generated through fusion of multiple protein coding and regulatory sequences. Conventional cloning techniques, including those involving restriction enzymes and ligases, are often of limited scope, in particular when many DNA fragments must be joined or scar-free fusions are mandatory. Overlap-based-cloning methods have the potential to overcome such limitations. One such method uses seamless ligation cloning extract (SLiCE) prepared from Escherichia coli cells for straightforward and efficient in vitro fusion of DNA fragments. Here, we systematically characterized extracts prepared from the unmodified E. coli strain DH10B for SLiCE-mediated cloning and determined DNA sequence-associated parameters that affect cloning efficiency. Our data revealed the virtual absence of length restrictions for vector backbone (up to 13.5 kbp) and insert (90 bp to 1.6 kbp). Furthermore, differences in GC content in homology regions are easily tolerated and the deletion of unwanted vector sequences concomitant with targeted fragment insertion is straightforward. Thus, SLiCE represents a highly versatile DNA fusion method suitable for cloning projects in virtually all molecular and synthetic biology projects.
合成生物学旨在设计和改造生物体。工程过程通常需要构建合适的DNA构建体,这些构建体通过融合多个蛋白质编码和调控序列产生。传统的克隆技术,包括那些涉及限制性内切酶和连接酶的技术,往往范围有限,特别是当需要连接多个DNA片段或必须进行无疤痕融合时。基于重叠的克隆方法有可能克服这些限制。其中一种方法是使用从大肠杆菌细胞制备的无缝连接克隆提取物(SLiCE),用于DNA片段的直接高效体外融合。在这里,我们系统地表征了从未经修饰的大肠杆菌菌株DH10B制备的用于SLiCE介导克隆的提取物,并确定了影响克隆效率的DNA序列相关参数。我们的数据显示载体骨架(高达13.5 kbp)和插入片段(90 bp至1.6 kbp)几乎没有长度限制。此外,同源区域中GC含量的差异很容易被容忍,并且在靶向片段插入的同时删除不需要的载体序列很简单。因此,SLiCE是一种高度通用的DNA融合方法,适用于几乎所有分子和合成生物学项目中的克隆项目。
