Intrinsically bent DNA in the promoter regions of the yeast GAAL1-10 and GAL80 genes

Circular permutation analysis has detected fairly strong sites of intrinsic DNA bending on the promoter regions of the yeast GAL1-10 and GAL80 genes. These bends lie in functionally suggestive locations. On the promoter of the GAL1-10 structural genes, strong bends bracket nucleosome B, which lies between the UAS(G) and the GAL1 TATA. These intrinsic bends could help position nucleosome B. Nucleosome B plus two other promoter nucleosomes protect the TATA and start site elements in the inactive state of expression but are completely disrupted (removed) when GAL1-10 expression is induced. The strongest intrinsic bend ( approximately 70 degrees ) lies at the downstream edge of nucleosome B; this places it approximately 30 base pairs upstream of the GAL1 TATA, a position that could allow it to be involved in GAL1 activation in several ways, including the recruitment of a yeast HMG protein that is required for the normally robust level of GAL1 expression in the induced state (Paull, T., Carey, M., and Johnson, R. (1996) Genes Dev. 10, 2769-2781). On the regulatory gene GAL80, the single bend lies in the non-nucleosomal hypersensitive region, between a GAL80-specific far upstream promoter element and the more gene-proximal promoter elements. GAL80 promoter region nucleosomes contain no intrinsically bent DNA.     

Histone H3 N-terminal mutations allow hyperactivation of the yeast GAL1 gene in vivo.

Recent work has shown that the yeast histone H4 N-terminus, while not essential for viability, is required for repression of the silent mating loci and activation of GAL1 and PHO5 promoters. Because histone H3 shares many structural features with histone H4 and is intimately associated with H4 in the assembled nucleosome, we asked whether H3 has similar functions. While the basic N-terminal domain of H3 is found to be non-essential (deletion of residues 4-40 of this 135 amino acid protein allows viability), its removal has only a minor effect on mating. Surprisingly, both deletions (of residues 4-15) and acetylation site substitutions (at residues 9, 14 and 18) within the N-terminus of H3 allow hyperactivation of the GAL1 promoter as well as a number of other GAL4-regulated genes including GAL2, GAL7 and GAL10. To a limited extent glucose repression is also alleviated by H3 N-terminal deletions. Expression of another inducible promoter, PHO5, is shown to be relatively unaffected. We conclude that the H3 and H4 N-termini have different functions in both the repression of the silent mating loci and in the regulation of GAL1.     

GAL4/UAS系统在转基因技术中的应用研究进展

GAL4/UAS系统是一种转基因技术体系,其原理是利用特定的启动子或增强子,以组织特异性的方式激活酵母转录激活子GAL4的表达,GAL4又以同样的方式引起GAL4反应元件(UAS)-靶基因的转录。GAL4/UAS系统的关键点在于:GAL4基因和UAS-靶基因分别存在于两个转基因系中。GAL4转基因系中有转录激活子,但没有靶基因;在UAS-靶基因系中,转录激活子不存在,因而靶基因处于沉默状态,只有将GAL4转基因系与UAS-靶基因系进行杂交,才可能产生表达靶基因的后代。本文综述了GAL4/UAS系统的建立及其研究应用。     

Global nucleosome occupancy in yeast

Background  

Although eukaryotic genomes are generally thought to be entirely chromatin-associated, the activated PHO5 promoter in yeast is largely devoid of nucleosomes. We systematically evaluated nucleosome occupancy in yeast promoters by immunoprecipitating nucleosomal DNA and quantifying enrichment by microarrays.