Louis J. Papa III, Matthew D. Shoulders
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引用次数: 2
Abstract
Recombineering inserts PCR products into DNA using homologous recombination. A pair of short homology arms (50 base pairs) on the ends of a PCR cassette target the cassette to its intended location. These homology arms can be easily introduced as 5′ primer overhangs during the PCR reaction. The flexibility to choose almost any pair of homology arms enables the precise modification of virtually any DNA for purposes of sequence deletion, replacement, insertion, or point mutation. Recombineering often offers significant advantages relative to previous homologous recombination methods that require the construction of cassettes with large homology arms, and relative to traditional cloning methods that become intractable for large plasmids or DNA sequences. However, the tremendous number of variables, options, and pitfalls that can be encountered when designing and performing a recombineering protocol for the first time introduce barriers that can make recombineering a challenging technique for new users to adopt. This article focuses on three recombineering protocols we have found to be particularly robust, providing a detailed guide for choosing the simplest recombineering method for a given application and for performing and troubleshooting experiments. © 2019 by John Wiley & Sons, Inc.
DNA重组的基因工程
重组是利用同源重组将PCR产物插入DNA中。一对短同源臂(50个碱基对)在PCR盒的末端将盒定位到预定位置。在PCR反应中,这些同源臂可以很容易地作为5 '引物悬垂引入。选择几乎任何一对同源臂的灵活性,使得几乎任何DNA的精确修饰,用于序列删除,替换,插入或点突变。相对于先前需要构建具有大同源臂的磁带的同源重组方法,以及相对于传统的克隆方法,重组通常具有显著的优势,而传统的克隆方法对于大质粒或DNA序列变得难以处理。然而,在第一次设计和执行重组协议时可能遇到的大量变量、选项和陷阱引入了障碍,使重组成为新用户难以采用的一项具有挑战性的技术。本文重点介绍了我们发现的三种特别健壮的重组协议,提供了为给定应用程序选择最简单的重组方法以及执行和故障排除实验的详细指南。©2019 by John Wiley &儿子,Inc。
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