一种基因破坏方法,可在构建多重破坏酵母菌株时重复使用URA3选择。
A method for gene disruption that allows repeated use of URA3 selection in the construction of multiply disrupted yeast strains.
作者信息
Alani E, Cao L, Kleckner N
出版信息
Genetics. 1987 Aug;116(4):541-5. doi: 10.1534/genetics.112.541.test.
Abstract
In this paper, we describe a 3.8-kb molecular construct that we have used to disrupt yeast genes. The construct consists of a functional yeast URA3 gene flanked by 1.1-kb direct repeats of a bacterial sequence. It is straightforward to insert the 3.8-kb segment into a cloned target gene of interest and then introduce the resulting disruption into the yeast genome by integrative transformation. An appropriate DNA fragment containing the disruption plus flanking homology can be obtained by restriction enzyme digestion. After introducing such fragments into yeast by transformation, stable integrants can be isolated by selection for Ura+. The important feature of this construct that makes it especially useful is that recombination between the flanking direct repeats occurs at a high frequency (10(-4)) in vegetatively grown cultures. After excision, only one copy of the repeat sequence remains behind. Thus in the resulting strain, the Ura+ selection can be used again, either to disrupt a second gene in similar fashion or for another purpose.
摘要
在本文中,我们描述了一种用于破坏酵母基因的3.8 kb分子构建体。该构建体由一个功能性酵母URA3基因组成,两侧是一段1.1 kb的细菌序列直接重复序列。将3.8 kb片段插入感兴趣的克隆目标基因中,然后通过整合转化将产生的破坏片段导入酵母基因组,这一过程很简单。通过限制性酶切可以获得包含破坏片段及侧翼同源序列的合适DNA片段。通过转化将此类片段导入酵母后,可以通过选择Ura+来分离稳定整合体。该构建体的一个使其特别有用的重要特征是,侧翼直接重复序列之间的重组在营养生长的培养物中以高频率(10^(-4))发生。切除后,仅留下一份重复序列拷贝。因此,在所得菌株中,Ura+选择可再次用于以类似方式破坏第二个基因或用于其他目的。
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