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.

Transcription of the ADH2 gene in Saccharomyces cerevisiae is limited by positive factors that bind competitively to its intact promoter region on multicopy plasmids.

Abstract: Transcription of the ADH2 gene in the yeast Saccharomyces cerevisiae was inhibited by excess copies of its own promoter region. This competition effect was promoter specific and required the upstream activation sequence of ADH2 as well as sequences 3' to the TATA box. Introducing excess copies of ADR1, an ADH2-specific regulatory gene, did not alleviate the competition that was observed in these circumstances during both constitutive and derepressed ADH2 expression. Excess copies of the upstream region did not release ADH2 from glucose repression, consistent with the view that ADH2 is regulated by positive trans-acting factors.

RNA sequences that work as transcriptional activating regions

Abstract: We describe a set of RNA molecules that work as transcriptional activators when tethered to DNA. These RNA activating regions were found amongst a randomized set of molecules bearing variants of a 10 nt loop attached to an RNA stem. The various RNA activating regions all bear an identical five- residue sequence with an interspersed sixth residue. The result shows that although all natural activating regions characterized thus far are peptidic, this function can be served by other kinds of moieties as well.

Highly conserved upstream sequences for transcription factor genes and implications for the regulatory network

Abstract: Identifying evolutionarily conserved blocks in orthologous genomic sequences is an effective way to detect regulatory elements. In this study, with the aim of elucidating the architecture of the regulatory network, we systematically estimated the degree of conservation of the upstream sequences of 3,750 human–mouse orthologue pairs along 8-kb stretches. We found that the genes with high upstream conservation are predominantly transcription factor (TF) genes. In particular, developmental process-related TF genes showed significantly higher conservation of the upstream sequences than other TF genes. Such extreme upstream conservation of the developmental process-related TF genes suggests that the regulatory networks involved with developmental processes have been evolutionarily well conserved in both human and mouse lineages.

An imperfect inverted repeat is critical for DNA binding of the response regulator RegR of Bradyrhizobium japonicum.

Abstract: RegR is the response regulator of the RegSR two-component regulatory system in Bradyrhizobium japonicum. The only target known so far is the fixR-nifA operon, encoding the redox-responsive transcription factor NifA, which activates many genes required for symbiotic nitrogen fixation in soybean nodules. In previous in vivo studies, we identified a 32 bp upstream activating sequence located around position –68, which is essential for RegR-dependent expression of the fixR-nifA operon. Here, we used an in vitro binding-site selection assay (SELEX) to more precisely define the DNA-binding specificity of RegR. The selected sequences comprised an imperfect inverted repeat (GCGGC-N5-GTCGC) which is highly similar to an imperfect inverted repeat in the fixR UAS (GCGAC-N5-GACGC). In a parallel approach, band-shift experiments were performed with oligonucleotides comprising defined point or deletion mutations in the fixR UAS. This led to the identification of 11 critical nucleotides within a 17 bp minimal RegR binding site centered at position –64 upstream of the fixR-nifA transcription start site. Notably, all 11 critical nucleotides were located either within the half sites of the inverted repeat (four nucleotides in each half site) or in the 5 bp spacer that separates the half sites (three nucleotides). Based on these results, we defined a DNA motif comprising those nucleotides that are critical for RegR binding (RegR box; 5′-GNGAGCAGTTNNGNCGC-3′). A comparison of the RegR box with functional binding sites of the RegR-like regulator RegA of Rhodobacter capsulatus revealed considerable similarities. Thus, the RegR box may assist in the identification of new RegR target genes not only in B.japonicum but also in other α-proteobacteria possessing RegR-like response regulators.

The core promoter of mouse rDNA consists of two functionally distinct domains

Abstract: We have determined the sequences constituting the minimal promoter of mouse rDNA. A very small region immediately upstream of the transcription start site (from -1 to -39) is sufficient to direct correct transcription initiation. Sequences immediately downstream of the transcription start site (+1 to +11) increase the efficiency of transcription initiation. Point mutations within the core promoter have been generated and assayed for their effects on template activity and on interaction with the pol I specific transcription factor TIF-IB. The core promoter element appears to consist of two functionally different domains. The distal sequence motif from position -22 to -16 is recognized by factor TIF-IB. Mutations within this region lead to similar changes of both template activity and binding of TIF-IB. Two point mutations within the proximal sequence motif from -15 to -1 do not affect TIF-IB binding although they severely impair transcription initiation. It is suggested, that this proximal region plays a role in the assembly of functional transcription initiation complexes rather than in the primary binding of TIF-IB.