Heather Conrad-Webb scite author profile

Transcription of ribosomal DNA by RNA polymerase I is believed to be the sole source of the 25S, 18S, and 5.8S rRNAs in wild-type cells of Saccharomyces cerevisiae. Here we present evidence for a switch from RNA polymerase I to RNA polymerase II in the synthesis of a substantial fraction of those rRNAs in respiratory-deficient (petite) cells. The templates for the RNA polymerase II transcripts are largely, if not exclusively, episomal copies of ribosomal DNA arising from homologous recombination events within the ribosomal DNA repeat on chromosome XII. Ribosomal DNA contains a cryptic RNA polymerase II promoter that is activated in petites; it overlaps the RNA polymerase I promoter and produces a transcript equivalent to the 35S precursor rRNA made by RNA polymerase I. Yeast cells that lack RNA polymerase I activity, because of a disruption of the RPA135 gene that encodes subunit II of the enzyme, can survive by using the RNA polymerase II promoter in ribosomal DNA to direct the synthesis of the 35S rRNA precursor. This polymerase switch could provide cells with a mechanism to synthesize rRNA independent of the controls of RNA polymerase I transcription.

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The nuclearSUV3-1mutation affects a variety of post-transcriptional processes in yeast mitochondria

Conrad-Webb¹,

Perlman²,

Zhu³

et al. 1990

Nucl Acids Res

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The SUV3-1 mutation was isolated earlier as a suppressor of a deletion of a conserved RNA processing site (dodecamer) near the 3' end of the var1 gene. Previous studies indicate that the suppressor enhances translation of mutant var1 messages; unexpectedly, it also causes over-accumulation of excised intron RNA of the large rRNA gene intron and blocks cleavage at the dodecamer site within that intron. In this study most mitochondrial genes in SUV3-1 and suv3 nuclear contexts are surveyed for changes in levels of mRNA, for interference with dodecamer cleavage and splicing and for levels of excised intron RNAs. SUV3-1 has little or no effect on the size or abundance of unspliced RNAs tested. It results, however, in a marked increase in the abundance of seven of eight excised group I intron RNAs tested, most of which are not detectable in wild-type (suv3) strains. The suppressor lowers levels of the cob and coxl mRNAs about 2-5 and 20-fold, respectively. The effect on coxl mRNA results from a decrease in the splicing of its intron 5 beta. Despite the reduction in these mRNA levels, the amounts of coxl and cyt b polypeptides were close to wild-type levels in SUV3-1 cells. These data show that the suv3 gene plays a prominent role in post-transcriptional and translation events in yeast mitochondria.

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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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The role of a conserved dodecamer sequence in yeast mitochondrial gene expression

Butow

Hong²,

Perlman³

et al. 1989

Genome

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All mRNAs on the yeast mitochondrial genome terminate at a conserved dodecamer sequence 5'-AAUAAUAUUCUU-3'. We have characterized two mutants with altered dodecamers. One contains a deletion of the dodecamer at the end of the var1 gene, and the other contains two adjacent transversions in the dodecamer at the end of the reading frame of fit1, a gene within the omega+ allele of the 21S rRNA gene. In each mutant, expression of the respective gene is blocked completely. A dominant nuclear suppressor, SUV3-1, was isolated that suppresses the var1 deletion but is without effect on the fit1 dodecamer mutations. Unexpectedly, however, we found that SUV3-1 blocks expression of the wild-type fit1 allele by blocking processing at its dodecamer. SUV3-1 has pleiotropic effects on mitochondrial gene expression, affecting RNA processing, RNA stability, and translation. Our results suggest that RNA metabolism and translation may be part of a multicomponent complex within mitochondria.

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Relocation of the unusualVAR1 gene from the mitochondrion to the nucleus

Sanchirico

Tzellas²,

Mason³

et al. 1995

Biochem. Cell Biol.

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The Var1 protein (Var1p) is an essential, stoichiometric component of the yeast mitochondrial small ribosomal subunit, and it is the only major protein product of the mitochondrial genetic system that is not part of an energy transducing complex of the inner membrane. Interestingly, no mutations have been reported that affect the function of Var1p, presumably because loss of a functional mitochondrial translation system leads to an instability of mtDNA. To study the structure, function and synthesis of Var1p, we have engineered yeast strains for the expression of this protein from a nuclear gene, VAR1U, in which 39 nonstandard mitochondrial codons were converted to the universal code. Immunoblot analysis using an epitope-tagged form of Var1Up showed that the nuclear-encoded protein was expressed and imported into the mitochondria. VAR1U was tested for its ability to complement a mutation in mtDNA, PZ206, which disrupts '3-end processing of the VARI mRNA, causing greatly reduced synthesis of Var1p and a respiratory-deficient phenotype. Respiratory growth was restored in PZ206 mutants by transformation with a centromere plasmid carrying VAR1U under ADH1 promoter control, thus proving that VAR1 function can be relocated from the mitochondrion to the nucleus. Moreover, epitope-tagged Var1Up co-sedimented specifically with small ribosomal subunits in high salt sucrose gradients. The relocation of VAR1 from the mitochondrion to the nucleus provides an excellent system for the molecular genetic analysis of structure-function relationships in the unusual Var1 protein.

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