GAGA因子通过单个三核苷酸序列元件与DNA结合。
GAGA factor binding to DNA via a single trinucleotide sequence element.
作者信息
Wilkins R C, Lis J T
机构信息
Section of Genetics and Development, Cornell University, Ithaca, NY 14853, USA.
出版信息
Nucleic Acids Res. 1998 Jun 1;26(11):2672-8. doi: 10.1093/nar/26.11.2672.
Abstract
GAGA transcription factor (GAF) is an essential protein in Drosophila , important for the transcriptional regulation of numerous genes. GAF binds to GA repeats in the promoters of these genes via a DNA-binding domain containing a single zinc finger. While GAF binding sites are typically composed of 3.5 GA repeats, the Drosophila hsp70 gene contains much smaller elements, some of which are as little as three bases (GAG) in length. Interestingly, the binding of GAF to more distant trinucleotide elements is relatively strong and not appreciably affected by the removal of larger GA arrays in the promoter. Moreover, a simple synthetic GAG sequence is sufficient to bind GAF in vitro . Here we directly compare the affinity of GAF for different sequence elements by immunoprecipitation and gel mobility shift analysis. Furthermore, our measures of the concentration of GAF in vivo indicate that it is a highly abundant nuclear protein, prevalent enough to occupy a sizable fraction of correspondingly abundant trinucleotide sites.
摘要
GAGA转录因子(GAF)是果蝇中的一种必需蛋白质,对众多基因的转录调控至关重要。GAF通过包含单个锌指的DNA结合结构域与这些基因启动子中的GA重复序列结合。虽然GAF结合位点通常由3.5个GA重复序列组成,但果蝇hsp70基因包含小得多的元件,其中一些长度只有三个碱基(GAG)。有趣的是,GAF与更远距离的三核苷酸元件的结合相对较强,并且不受启动子中较大GA阵列去除的明显影响。此外,一个简单的合成GAG序列在体外就足以结合GAF。在这里,我们通过免疫沉淀和凝胶迁移率变动分析直接比较了GAF对不同序列元件的亲和力。此外,我们对体内GAF浓度的测量表明,它是一种高度丰富的核蛋白,普遍存在,足以占据相当一部分相应丰富的三核苷酸位点。
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