C. A. F. M. Van Der Sande scite author profile

Making use of an rDNA unit, containing oligonucleotide tags in both the 17S and 26S rRNA gene, we have analyzed the effect of various deletions in the External Transcribed Spacer (ETS) and in one of the Internal Transcribed Spacers 1 (ITS1) on the process of ribosome formation in yeast. By following the fate of the tagged transcripts of this rDNA unit in vivo by Northern hybridization we found that deleting various parts of the ETS prevents the accumulation of tagged 17S rRNA and its assembly into 40S subunits, but not the formation of 60S subunits. Deleting the central region of ITS1, including a processing site that is used in an early stage of the maturation process, was also found to prevent the accumulation of functional 49 S subunits, whereas no effect on the formation of 60S subunits was detected. The implications of these findings for yeast pre‐rRNA processing are discussed.

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Separate structural elements within internal transcribed spacer 1 ofSaccharomyces cerevisiaeprecursor ribosomal RNA direct the formation of 17S and 26S rRNA

Nues

et al. 1994

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Structural features of Internal Transcribed Spacer 1 (ITS1) that direct its removal from Saccharomyces cerevisiae pre-rRNA during processing were identified by an initial phylogenetic approach followed by in vivo mutational analysis of specific structural elements. We found that S. cerevisiae ITS1 can functionally be replaced by the corresponding regions from the yeasts Torulaspora delbrueckii, Kluyveromyces lactis and Hansenula wingei, indicating that structural elements required in cis for processing are evolutionarily conserved. Despite large differences in size, all ITS1 regions conform to the secondary structure proposed by Yeh et al. [Biochemistry 29 (1990) 5911-5918], showing five domains (I-V; 5'-->3') of which three harbour an evolutionarily highly conserved element. Removal of most of domain II, including its highly conserved element, did not affect processing. In contrast, highly conserved nucleotides directly downstream of processing site A2 in domain III play a major role in production of 17S, but not 26S rRNA. Domain IV and V are dispensable for 17S rRNA formation although an alternative, albeit inefficient, processing route to mature 17S rRNA may be mediated by a conserved region in domain IV. Each of these two domains is individually sufficient for efficient production of 26S rRNA, suggesting two independent processing pathways. We conclude that ITS1 is organized into two functionally and structurally distinct halves.

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Functional analysis of internal transcribed spacer 2 of Saccharomyces cerevisiae ribosomal DNA

Sande

Kwa

Nues

et al. 1992

Journal of Molecular Biology

153

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The cellular level of yeast ribosomal protein L25 is controlled principally by rapid degradation of excess protein

et al. 1986

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When the gene dosage for the primary rRNA-binding ribosomal protein L25 in yeast cells was raised about 50-fold, the level of mature L25 transcripts was found to increase almost proportionally. The plasmid-derived L25 transcripts were structurally indistinguishable from their genomic counterparts, freely entered polysomes in vivo and were fully translatable in a heterologous in vitro system. Nevertheless, pulse-labelling for periods varying from 3-20 min did not reveal a significant elevation of the intracellular level of L25-protein. When pulse-times were decreased to 10-45 s, however, we did detect a substantial overproduction of L25. We conclude that, despite the strong RNA-binding capacity of the protein, accumulation of L25 is not controlled by an autogenous (pre-)mRNA-targeted mechanism similar to that operating in bacteria, but rather by extremely rapid degradation of excess protein produced.

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A system to study transcription by yeast RNA polymerase I within the chromosomal context: functional analysis of the ribosomal DNA enhancer and the RBP1/REB1 binding sites.

et al. 1992

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We have developed a novel system to study transcription by yeast RNA polymerase I (Pol I) of mutated rDNA units within the chromosomal context. For this, complete rDNA units carrying specific oligonucleotide tags in both the 17S and 26S rRNA genes were integrated into the chromosomal rDNA locus. Using this novel system, we analysed the action of the rDNA enhancer in stimulating transcription within the chromosomal context. We found that the enhancer acts as a stimulatory element in both directions, mainly on its two most proximal rRNA operons. Deletion of the sequences between the enhancer and the Pol I promoter in the tagged, integrated unit indicated that this part of the intergenic spacer contains no other transcriptional regulatory elements for Pol I. We also applied the system to study the function of the rDNA binding protein RBP1/REB1. For this purpose, we analysed tagged units in which either one or both of the binding sites for this protein have been inactivated. We found that mutations of both binding sites strongly diminish the transcription of the adjacent operon. The protein is hypothesized to play a crucial role in keeping the chromosomal rDNA units in an optimal spatial configuration by anchoring consecutive enhancers and promoters to the nucle(ol)ar matrix.

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