Upstream activating sequence

About: Upstream activating sequence is a research topic. Over the lifetime, 1633 publications have been published within this topic receiving 100112 citations.

Two distinct promoter elements in the human rRNA gene identified by linker scanning mutagenesis.

Abstract: A cell-free RNA polymerase I transcription system was used to evaluate the transcription efficiency of 21 linker scanning mutations that span the human rRNA gene promoter. Our analysis revealed the presence of two major control elements, designated the core and upstream elements, that affect the level of transcription initiation. The core element extends from -45 to +18 relative to the RNA start site, and transcription is severely affected (up to 100-fold) by linker scanning mutations in this region. Linker scanning and deletion mutations in the upstream element, located between nucleotides -156 and -107, cause a three- to fivefold reduction in transcription. Under certain reaction conditions, such as the presence of a high ratio of protein to template or supplementation of the reaction with partially purified protein fractions, sequences upstream of the core element can have an even greater effect (20- to 50-fold) on RNA polymerase I transcription. Primer extension analysis showed that RNA synthesized from all of these mutant templates is initiated at the correct in vivo start site. To examine the functional relationship between the core and the upstream region, mutant promoters were constructed that alter the orientation, distance, or multiplicity of these control elements relative to each other. The upstream control element appears to function in only one orientation, and its position relative to the core is constrained within a fairly narrow region. Moreover, multiple core elements in close proximity to each other have an inhibitory effect on transcription.

Genetic properties and chromatin structure of the yeast gal regulatory element: an enhancer-like sequence

Abstract: DNA molecules created by fusing a 365-base-pair segment of yeast DNA encoding the galactose-regulated upstream promoter element (gal) to a set of derivatives that systematically delete sequences upstream from the his3 gene are introduced in single copy back into the yeast genome precisely at the his3 locus and then assayed for transcription. Fusions of the gal regulatory element to his3 derivatives containing all normal mRNA coding sequences but lacking essentially the entire promoter region fail to express his3 under any growth conditions. Fusions to derivatives lacking the his3 upstream promoter element but containing the "TATA box" place his3 expression under gal control--i.e., extremely high RNA levels in galactose-containing medium and essentially no his3 RNA in glucose-containing medium. However, of the two normal his3 initiation sites, only the downstream one is activated by the gal element. In fusions of this type, neither the orientation of the gal element nor the distance between the element and the his3 TATA box affects the level or the initiation points of transcription. However, the gal element does not influence transcription when placed 100 or 300 base pairs downstream from the normal mRNA start sites. Fusions to derivatives containing the entire his3 promoter region restore the basal level of his3 transcription in glucose-grown cells, and both transcriptional initiation sites are used. Furthermore, RNA levels in galactose-grown cells, although somewhat higher than in glucose-grown cells, are significantly below the fully induced level. The distance from his3 coding sequences does not affect RNA levels, suggesting that specific sequences, possibly corresponding to the his3 upstream promoter element, reduce the ability of the gal element to activate transcription. Analysis of chromatin from some of these strains indicates a DNase I-hypersensitive site(s) in the middle of the gal element. However, this structural feature is not correlated with transcriptional initiation because it is found when cells are grown in glucose medium and also in derivatives lacking a TATA box. Thus, the gal upstream element possesses most, but not all, of the properties of viral and cellular enhancer sequences of higher eukaryotes. In addition, it appears that the his3 and gal upstream sequences represent two distinct classes of promoter elements, which activate transcription from different initiation sites.

Regulatory DNA elements localized remotely upstream from the drug-metabolizing cytochrome P-450c gene.

Abstract: We have investigated regulatory DNA elements in the expression of the drug metabolizing P-450c gene of rats. After combining the 5' flanking and upstream untranslated regions of the isolated P-450c gene with structural gene for chloramphenicol acetyltransferase (CAT), the fusion genes were transfected into cultured cells (Hepa-1 and L cells) for the assay of transient expression of CAT activity. CAT activity was expressed inducibly in response to 3-methylcholanthrene only in Hepa-1 cells. At least three regions containing regulatory DNA elements were indentified; one, which is present in the sequence from -44b to -0.2kb immediately upstream of the TATA box, functions in the basal level of transcription, and the other two which were located in the sequence from -0.8kb to -1.0kb and from -1.0kb to -6.3kb, enhance in combination, transcription in response to inducers in a manner independent of their orientation.

A heterodimer of the Zn2Cys6 transcription factors Pip2p and Oaf1p controls induction of genes encoding peroxisomal proteins in Saccharomyces cerevisiae.

Abstract: In the yeast Saccharornyces cerevisiae, two transcriptional activators belonging to the Zn2Cys6 protein family, Pip2p and Oaf1p, are involved in fatty-acid-dependent induction of genes encoding peroxisomal proteins. This induction is mediated via an upstream activation sequence called the oleate-response element (ORE). DNA-bandshift experiments with ORE probes and epitope-tagged proteins showed that two binary complexes occurred: in wild-type cells the major complex consisted of a Pip2p · Oaf1p heterodimer, but in cells in which Oaf1p was overexpressed an Oaf1p homodimer was also observed. The genes encoding Oaf1p and Pip2p were controlled in different ways. The OAF1 gene was constitutively expressed, while the PIP2 gene was induced upon growth on oleate, giving rise to positive autoregulatory control. We have shown that the Pip2p · Oaf1p heterodimer is responsible for the strong expression of the genes encoding peroxisomal proteins upon growth on oleate. Pip2p and Oaf1p form an example of a heterodimere of yeast Zn2Cys6 zinc-finger proteins binding to DNA.