Reid Robert J D, Lisby Michael, Rothstein Rodney
Department of Genetics and Development, Columbia University College of Physicians and Surgeons, New York, New York 10032, USA.
Methods Enzymol. 2002;350:258-77. doi: 10.1016/s0076-6879(02)50968-x.
Each of the adaptamer-directed genome manipulation methods is predicated on the fact that recombination between two DNAs is enhanced by increasing the length of homology. Many of the current PCR-based genome manipulation techniques rely on very short homologies to promote recombination. In these cases homology length is dictated by the technical limits of oligonucleotide synthesis. Adaptamers circumvent this problem since long homology regions are produced in a first round of PCR, and then fused to the selectable marker in a second round of PCR via complementary sequence tags on the adaptamers. Furthermore, many of the techniques described here rely on preexisting and commercially available adaptamer sets that can be obtained inexpensively rather than designing new primers for every experiment. Although a cost is incurred when performing multiple PCR amplifications, the increase in recombination efficiency is dramatic. Finally, the adaptamer-mediated PCR fusion methodology is versatile and can be applied to varied genome manipulations.
每种适配体导向的基因组操作方法都基于这样一个事实,即通过增加同源性长度可增强两个DNA之间的重组。当前许多基于PCR的基因组操作技术依靠非常短的同源性来促进重组。在这些情况下,同源性长度由寡核苷酸合成的技术限制决定。适配体规避了这个问题,因为在第一轮PCR中产生长同源区域,然后在第二轮PCR中通过适配体上的互补序列标签将其与选择标记融合。此外,这里描述的许多技术依赖于预先存在的且可廉价获得的适配体集,而不是为每个实验设计新引物。尽管进行多次PCR扩增会产生成本,但重组效率的提高非常显著。最后,适配体介导的PCR融合方法具有通用性,可应用于各种基因组操作。