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.

Characterization of the promoter of the large ribosomal RNA gene in yeast mitochondria and separation of mitochondrial RNA polymerase into two different functional components.

Abstract: We have characterized a DNA sequence that functions in recognition of the promoter of the mitochondrial large rRNA gene by the yeast mtRNA polymerase. Promoter-containing DNA fragments were mutagenized and used as templates to study initiation of transcription in vitro with a partially purified mtRNA polymerase preparation. Deletion mutants, in which increasing stretches of DNA were removed from regions flanking the promoter, define a short area essential for correct initiation of transcription. It virtually coincides with a highly conserved stretch of nine nucleotides that is found immediately upstream of all transcriptional start sites described thus far. Two different point mutations within this nonanucleotide sequence drastically reduce promoter function. Conversely a single point mutation that results in the formation of a nonanucleotide sequence 99 nucleotides upstream of the large rRNA gene leads to a new, efficient transcription initiation site. MtRNA polymerase can be resolved into two different components by chromatography on Blue Sepharose: one retaining the capacity to synthesize RNA, the other conferring the correct specificity of initiation to the catalytic component.

Enhancer and silencerlike sites within the transcribed portion of a Ty2 transposable element of Saccharomyces cerevisiae.

Abstract: The Ty2-917 element is a member of the Ty2 class of retroviruslike transposable elements of Saccharomyces cerevisiae. We showed that regions downstream of the Ty2-917 transcription start site modulate its transcription. One region was located downstream of the transcription initiation site (position 240) and within the first 559 base pairs of the element. This region had a dramatic effect, causing an approximately 1,000-fold increase in steady-state levels of RNA. The region stimulated transcription when placed in either orientation upstream of a heterologous gene, HIS4, lacking its own upstream activation sequence (UAS). We termed this positively acting region an enhancer, by analogy to sites described in higher cells, to distinguish it from yeast UASs which do not function when placed within the transcribed portion of the gene. Though, like some higher eucaryotic enhancers, the Ty2-917 enhancer is located within the transcribed region, it is unlike them in that it occurs within a coding region rather than in an intron. The Ty2-917 enhancer and the Ty2-917 UAS had a synergistic effect on transcription, together stimulating transcription 15-fold over the predicted additive effect. We also identified a site which decreases RNA accumulation, located about 750 base pairs into the element. This site functioned in only one orientation when inserted upstream of the UAS-less heterologous gene. The site was similar to silencers, or negative enhancers, in that it acted to repress transcription from outside the transcribed region, but was distinct in that the function of a canonical silencer was independent of orientation.

Identification and characterization of multiple A/T-rich cisacting elements that control expression from Dictyostelium actin promoters: the Dictyostelium actin upstream activating sequence confers growth phase expression and has enhancer-like properties

Abstract: The promoter elements in the Dictyostelium actin 15 and actin 6 genes required for full growth phase expression were identified by assaying promoter/luciferase reporter constructs. We find that these promoters contain common cis-acting elements, an actin upstream activating sequence (UAS) and sequences proximal to the transcription start site that overlap with a poly(dT) region. The actin 15 promoter has two additional cis-acting elements not present in the actin 6 promoter that may account for the higher level of expression from the actin 15 promoter. All of the identified promoter elements are unusual for Dictyostelium in that they are all A/T-rich. Two cis-acting elements, the actin UAS and the poly(dT) domain were studied in greater detail. The actin UAS was tested on a heterologous promoter from the prespore-specific gene SP60 and shown to have the ability to confer growth phase expression. The actin UAS also exhibited the ability to function in a distance- and orientation-independent manner and activate expression synergistically when present in two copies. The poly(dT) domain of the actin 15 promoter was studied in greater detail by using a genetic selection scheme to define parameters that effect the strength of this element. This element is comprised of 45 consecutive dT residues immediately upstream of the putative TATA box. We show that the length of the homopolymer dT region correlates with the expression level of the promoter. The poly(dT) element is also shown to function to promote wild-type levels of expression with small deviations in the sequence, indicating that the element is not required to be homopolymeric to function.