在一个进化上保守的DNA结合结构域中使酵母转录调节蛋白簇失活的突变。
Mutations that inactivate a yeast transcriptional regulatory protein cluster in an evolutionarily conserved DNA binding domain.
作者信息
Johnston M, Dover J
出版信息
Proc Natl Acad Sci U S A. 1987 Apr;84(8):2401-5. doi: 10.1073/pnas.84.8.2401.
Abstract
The protein encoded by the GAL4 gene of the yeast Saccharomyces cerevisiae binds to DNA upstream of several genes and activates transcription. To try to understand these processes, we have undertaken a genetic analysis of GAL4. Here we report that nearly all missense mutations in GAL4, selected in vivo to lack function of the protein, cluster in the small region of the gene that encodes the DNA binding domain. About half of these mutations alters a cysteine-rich region of the protein highly homologous to several eukaryotic DNA binding proteins; the other half alters some of the 20 amino acids adjacent to the cysteine-rich region. Nearly all of the missense mutations that alter the DNA binding domain abolish the DNA binding activity of GAL4 protein measured in vitro. In contrast, nearly all of the mutations that alter the 3' 95% of the gene that encodes the transcription activation function are nonsense or frameshift mutations. These results support the idea that the conserved cysteine-rich sequence motif is directly involved in binding of several eukaryotic transcriptional regulatory proteins to DNA.
摘要
酿酒酵母GAL4基因编码的蛋白质与几个基因上游的DNA结合并激活转录。为了试图理解这些过程,我们对GAL4进行了遗传分析。在此我们报告,在体内选择的几乎所有缺乏该蛋白质功能的GAL4错义突变,都聚集在该基因编码DNA结合结构域的小区域内。这些突变中约一半改变了该蛋白质富含半胱氨酸的区域,该区域与几种真核DNA结合蛋白高度同源;另一半改变了富含半胱氨酸区域附近的20个氨基酸中的一些。几乎所有改变DNA结合结构域的错义突变都消除了体外测量的GAL4蛋白的DNA结合活性。相反,几乎所有改变编码转录激活功能的基因3'端95%的突变都是无义或移码突变。这些结果支持这样一种观点,即保守的富含半胱氨酸序列基序直接参与几种真核转录调节蛋白与DNA的结合。
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