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.

cis- and trans-acting regulatory elements of the yeast URA3 promoter.

Abstract: Expression of the yeast pyrimidine biosynthetic gene, URA3, is induced three- to fivefold in response to uracil starvation, and this regulation is mediated by the transcriptional activator PPR1 (pyrimidine pathway regulator 1). In this study, we have analyzed the regulatory elements of the URA3 promoter by DNase I footprinting, using partially purified yeast cell extracts, by deletion mutagenesis, and by 5'-end mapping of RNA transcripts. Two DNA-binding activities have been detected, and at least four distinct cis-acting regions have been identified. A region rich in poly(dA-dT) serves as an upstream promoter element necessary for the basal level of URA3 expression. A 16-base-pair sequence with dyad symmetry acts acts as a uracil-controlled upstream activating site (UASURA) and shows a specific binding only with cell extracts from strains overproducing PPR1. This in vitro binding does not require dihydroorotic acid, the physiological inducer of URA3. The TATA region appears to be composed of two functionally distinct (constitutive and regulatory) elements. Two G + A-rich regions surrounding this TATA box bind an unidentified factor called GA-binding factor. The 5' copy, GA1, is involved in PPR1 induction and overlaps the constitutive TATA region. The 3' region, GA2, is necessary for maximal expression. Neither of these GA sequences acts as a UAS in a CYC1-lacZ context. The promoters of the unlinked but coordinately regulated URA1 and URA4 genes contain highly conserved copies of the UASURA sequence, which prompted us to investigate the effects of many point mutations within this UASURA sequence on PPR1-dependent binding. In this way, we have identified the most important residues of this binding site and found that a nonsymmetrical change of these bases is sufficient to prevent the specific binding and to suppress the UASURA activity in vivo. In addition, we showed that UASURA contains a constitutive activating element which can stimulate transcription from a heterologous promoter independently of dihydroorotic acid and PPR1.

Transcription activation at Class II CRP-dependent promoters: the role of different activating regions

Abstract: Transcription activation by the Escherichia coli cyclic AMP receptor protein (CRP) at Class II promoters is dependent on direct interactions between two surface-exposed activating regions (AR1 and AR2) and two contact sites in RNA polymerase. The effects on transcription activation of disrupting either AR1 or AR2 have been measured at different Class II promoters. AR2 but not AR1 is essential for activation at all the Class II promoters that were tested. The effects of single positive control substitutions in AR1 and AR2 vary from one promoter to another: the effects of the different substitutions are contingent on the -35 hexamer sequence. Abortive initiation assays have been used to quantify the effects of positive control substitutions in each activating region on the kinetics of transcription initiation at the Class II CRP- dependent promoter pmelRcon. At this promoter, the HL159 substitution in AR1 results in a defect in the initial binding of RNA polymerase whilst the KE101 substitution in AR2 reduces the rate of isomerization from the closed to the open complex.

A mutant spacer sequence between -35 and -10 elements makes the Plac promoter hyperactive and cAMP receptor protein-independent.

Abstract: To determine whether the spacer region between the -35 and -10 elements plays any sequence-specific role, we randomized the GC-rich sequence (-20CCGGCTCG-13) within the spacer region of the cAMP-dependent lac promoter and selected an activator-independent mutant, which showed extraordinarily high intrinsic activity. The hyperactive promoter is obtained by incorporation of a specific 10-bp-long AT-rich DNA sequence within the spacer, referred to as the -15 sequence, which must be juxtaposed to the upstream end of the -10 sequence for the hyperactivity. The transcription enhancement functions only in the presence of a -35 element. The spacer sequence enhanced both RNA polymerase binding and open complex formation. Isolated in the lac promoter, it also enhanced transcription when placed at two other unrelated promoters. Sequence analysis shows a low GC content and an abundance of stereochemically flexible TG:CA and TA:TA dimeric steps in the -18/-9 region and a strong correlation between the presence of flexible dimeric steps in this region and the intrinsic strength of the promoter.