Transcription of spacer sequences flanking the rat 45S ribosomal DNA gene.

Harrington, C A; Chikaraishi, Dona M.

doi:10.1128/mcb.7.1.314

Cited by 20 publications

(14 citation statements)

References 43 publications

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“…This is certainly its major effect in our assays, and it is also likely to be quite significant in vivo on the endogenous mammalian rRNA genes because polymerases clearly do approach the initiation region from upstream. These spacer polymerases include ones that initiated at promoters in the rDNA spacer (Cassidy et al 1987;Harrington and Chikaraishi 1987;Kuhn and Grummt 1987;Tower et al 1989) and possibly also ones that failed to terminate at the 3' end of the previous tandem rRNA gene. A terminator element could, however, have other positive effects on transcription as well.…”

Section: Discussionmentioning

confidence: 99%

The promoter-proximal rDNA terminator augments initiation by preventing disruption of the stable transcription complex caused by polymerase read-in.

Henderson¹,

Ryan²,

Sollner‐Webb³

1989

Genes Dev.

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We have examined the mechanism by which transcriptional initiation at the mouse rDNA promoter is augmented by the RNA polymerase I terminator element that resides just upstream of it. Using templates in which terminator elements are instead positioned at the opposite side of the plasmid rather than proximal to the promoter, or conditions where transcription is terminated elsewhere in the plasmid by UV-induced lesions, we show that the terminator's stimulatory effect is not position dependent. Mouse terminator elements therefore do not stimulate via the previously postulated 'read-through enhancement' model in which terminated polymerases are handed off to an adjacent promoter in a concerted reaction. The position independence and orientation dependence of the terminator also makes it unlikely that the terminator functions as a promoter element or as an enhancer. Instead, terminators serve to augment initiation by preventing polymerases from reading completely around the plasmid and through the promoter from upstream, an event which we show interferes with subsequent rounds of initiation. Notably, this transcriptional interference arises because polymerase passage across a promoter disrupts the otherwise stable transcription complex, specifically releasing the bound transcription factor D. These liberated D molecules can then bind to other templates and activate their expression. The rDNA transcriptional interference is not due to a steric impediment to the binding of new polymerase molecules, and it does not similarly liberate the initiationcompetent polymerase {factor C). These studies have also convincingly demonstrated that multiple rounds of transcription are obtained from rDNA template molecules in vitro.

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Section: Discussionmentioning

confidence: 99%

The promoter-proximal rDNA terminator augments initiation by preventing disruption of the stable transcription complex caused by polymerase read-in.

Henderson¹,

Ryan²,

Sollner‐Webb³

1989

Genes Dev.

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“…While mouse rDNA evidently does not contain spacer promoters within -1. 8 kilobase pairs (kbp) upstream from the gene promoter (46), nuclear run-on transcription data (15) in conjunction with in vitro runoff transcription data (13) suggest that an initiation site might exist within the adjoining several-hundred-basepair region. Furthermore, the identification of transcriptional terminators immediately upstream of mammalian gene promoters (13,16) has also indicated that transcripts read toward the gene promoter from the spacer.…”

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confidence: 99%

An RNA polymerase I promoter located in the CHO and mouse ribosomal DNA spacers: functional analysis and factor and sequence requirements.

Tower¹,

Henderson²,

Dougherty³

et al. 1989

Mol. Cell. Biol.

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We report results of experiments in which we demonstrated the existence of a polymerase I promoter within the ribosomal DNA spacer upstream from the rRNA initiation site in Chinese hamsters and mice. Transcription of the CHO spacer promoter was achieved by the same protein factors, C and D, that catalyzed transcription of the gene promoter, and these factors bound stably to the CHO spacer promoter in a preinitiation complex, just as they did to the gene promoter. In contrast to the CHO spacer promoter, which was transcribed in vitro nearly as efficiently as the gene promoter, the mouse spacer promoter was far less active; this low activity was attributable to the fact that the mouse spacer promoter bound factor D inefficiently. It is striking that the active CHO spacer promoter violated the otherwise universal rule that metazoan RNA polymerase I promoters all have a G residue at position -16. Sequence comparisons also revealed a great similarity between the CHO and mouse spacer promoter regions, yet there was much less similarity between the flanking sequences. There was also only limited homology between the spacer and gene promoter regions, but despite this the two kinds of initiation regions were organized similarly, both consisting of an essential core promoter domain and a stimulatory domain that extended upstream to approximately residue -135. Evolutionary considerations argue strongly that the presence of ribosomal DNA spacer promoters offers a significant selective advantage.Although it is frequently stated that the rRNA gene promoter is the only site at which RNA polymerase I initiates transcription, it has been known for several years that the spacer regions separating adjacent rRNA genes in a number of invertebrate and lower vertebrate species contain repeated elements that are related to the gene promoter. In members of the genera Xenopus, Drosophila, and Artemia, the ribosomal DNA (rDNA) spacer contains two to five spacer promoters whose sequences are highly homologous to those of the respective gene promoters and which exhibit promoter activity in vitro, in vivo, or both (1, 12, 18, 19, 27, 29, 32-34, 37, 43). In Xenopus laevis, both the spacer promoters and adjoining 60-and 81-base-pair (bp) repetitive elements, which are duplications of the central region of the gene promoter, have been shown to affect transcription (6,7,36) and recently have been demonstrated to enhance expression from adjoining rRNA gene promoters (L. Pape, J. Windle, and B. Sollner-Webb, submitted for publication). In addition, an intergenic sequence element in yeast rDNA which has been reported to possess promoter activity in vitro (40) also acts as a yeast rRNA gene enhancer element in vivo (9, 10).In part because of its much greater size, the spacer region of mammalian rDNA repeats remains largely uncharacterized. However, the presence of spacer promoters in many diverse lower organisms suggested that such elements may also exist in mammalian spacer regions. While mouse rDNA evidently does not contain spacer promoters with...

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“…This result was surprising for at least two reasons. First, although it is now recognized that NTS sequences are transcribed in some organisms (9,23,25,35,36), those transcripts appear to be very unstable and have not been found to accumulate in cells to any appreciable extent. Second, the relationship between the relative abundance of NTS transcripts and the functional state of mitochondria or the mitochondrial genome was not immediately obvious.…”

mentioning

confidence: 99%

Interaction between the yeast mitochondrial and nuclear genomes influences the abundance of novel transcripts derived from the spacer region of the nuclear ribosomal DNA repeat.

Parikh¹,

Conrad-Webb²,

Docherty³

et al. 1989

Mol. Cell. Biol.

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We have identified stable transcripts from the so-called nontranscribed spacer region (NTS) of the nuclear ribosomal DNA repeat in certain respiration-deficient strains of Saccharomyces cerevisiae. These RNAs, which are transcribed from the same strand as is the 37S rRNA precursor, are 500 to 800 nucleotides long and extend from the 5' end of the 5S rRNA gene to three major termination sites about 1,780, 1,830, and 1,870 nucleotides from the 3' end of the 26S rRNA gene. A survey of various wild-type and respiration-deficient strains showed that NTS transcript abundance depended on the mitochondrial genotype and a single codominant nuclear locus. In strains with that nuclear determinant, NTS transcripts were barely detected in [rho'] cells, were slightly more abundant in various mit-derivatives, and were most abundant in petites. However, in one petite that was hypersuppressive and contained a putative origin of replication (ori5) within its 757-base-pair mitochondrial genome, NTS transcripts were no more abundant than in [rho'] cells. The property of low NTS transcript abundance in the hypersuppressive petite was unstable, and spontaneous segregants that contained NTS transcripts as abundant as in the other petites examined could be obtained. Thus, respiration deficiency per se is not the major factor contributing to the accumulation of these unusual RNAs. Unlike RNA polymerase I transcripts, the abundant NTS RNAs were glucose repressible, fractionated as poly(A)+ RNAs, and were sensitive to inhibition by 10 ,ug of a-amanitin per ml, a concentration that had no effect on rRNA synthesis. Abundant NTS RNAs are therefore most likely derived by polymerase H transcription.Although the products of many nuclear genes and a few encoded by the mitochondrial genome are required for the synthesis of functional mitochondria, the molecular interactions between these organelles, which are required to achieve balanced mitochondrial synthesis, are still poorly understood. Expression of some nuclear genes encoding mitochondrial proteins is known to be regulated according to growth conditions and to various metabolic demands of the cell. In the yeast Saccharomyces cerevisiae, for example, growth of cells on high glucose concentrations represses the synthesis of nuclear-encoded components of the oxidative phosphorylation apparatus (55,62). Yeast cells also have a regulatory network that adjusts the synthesis of mitochondrial heme proteins in response to fluctuations in the levels of heme (21). These regulatory pathways operate through interactions between trans-acting factors encoded at loci such as HAP], HAP2, and HAP3 and their target, cis-acting sites located upstream of the relevant genes (22, 44 46, 58).Other nuclear genes have been identified which control mitochondrial gene expression in that their products exert specific control over mitochondrial RNA processing (3,13,14), mRNA stability (13-15), and translation (11,47,52 that the functional state of mitochondria, or the mitochondrial genotype, could influence the expre...

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Transcription of spacer sequences flanking the rat 45S ribosomal DNA gene.

Cited by 20 publications

References 43 publications

The promoter-proximal rDNA terminator augments initiation by preventing disruption of the stable transcription complex caused by polymerase read-in.

The promoter-proximal rDNA terminator augments initiation by preventing disruption of the stable transcription complex caused by polymerase read-in.

An RNA polymerase I promoter located in the CHO and mouse ribosomal DNA spacers: functional analysis and factor and sequence requirements.

Interaction between the yeast mitochondrial and nuclear genomes influences the abundance of novel transcripts derived from the spacer region of the nuclear ribosomal DNA repeat.

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