Transcription in yeast mitochondria: analysis of the 21 S rRNA region and its transcripts

Sequence analysis of three mitochondrial DNA molecules reveals interesting differences among Saccharomyces yeasts

The complete sequences of mitochondrial DNA (mtDNA) from the two budding yeasts Saccharomyces castellii and Saccharomyces servazzii, consisting of 25 753 and 30 782 bp, respectively, were analysed and compared to Saccharomyces cerevisiae mtDNA. While some of the traits are very similar among Saccharomyces yeasts, others have highly diverged. The two mtDNAs are much more compact than that of S.cerevisiae and contain fewer introns and intergenic sequences, although they have almost the same coding potential. A few genes contain group I introns, but group II introns, otherwise found in S.cerevisiae mtDNA, are not present. Surprisingly, four genes (ATP6, COX2, COX3 and COB) in the mtDNA of S.servazzii contain, in total, five +1 frameshifts. mtDNAs of S.castellii, S.servazzii and S.cerevisiae contain all genes on the same strand, except for one tRNA gene. On the other hand, the gene order is very different. Several gene rearrangements have taken place upon separation of the Saccharomyces lineages, and even a part of the transcription units have not been preserved. It seems that the mechanism(s) involved in the generation of the rearrangements has had to ensure that all genes stayed encoded by the same DNA strand.

The DExH box protein Suv3p is a component of a yeast mitochondrial 3'-to-5' exoribonuclease that suppresses group I intron toxicity

The yeast mitochondrial protein Suv3p is a putative NTP-dependent RNA helicase. Here we report that in cells lacking Suv3p, there is an approximately 50-fold increase in the excised form of the group I intron omega of the mitochondrial 31S rRNA gene. Surprisingly, little mature 21S rRNA accumulates in those cells; instead, unligated 21S rRNA exons appear. Intron overaccumulation could lead to spliced exon reopening via a reaction known to be catalyzed by group I introns in vitro. We also show that Suv3p is a functional component of a novel mitochondrial NTP-dependent 3'-to-5' exoribonuclease activity that can degrade group I intron RNAs. These findings account for group I intron overaccumulation in cells lacking Suv3p and define a novel function for putative RNA helicases in direct RNA degradation.

The suv3 nuclear gene product is required for the in vivo processing of the yeast mitochondrial 21s rRNA transcripts containing the r1 intron

We have constructed a yeast mitochondrial genome containing only one group-I intron, r1, from the 21s rRNA gene and introduced this genome into a strain bearing a disruption of the suv3 gene. The presence of the r1 intron alone causes a block in respiration, while the isogenic strain containing the intronless genome is respiratory competent. Northern analysis indicates that the functional suv3 protein is necessary for the yeast cell in order to process the r1-containing transcripts: in the absence of the suv3 protein the hybridization pattern of the excised r1 intron is altered and the amount of mature 21s rRNA is 50-fold lower. We suggest that the multifunctional suv3 protein, which displays motifs of ATP-dependent RNA helicases, is necessary for the in vivo pathway leading to formation of mature 21s rRNA from the transcripts containing the r1 intron in mitochondria of Saccharomyces cerevisiae.

A nucleoside triphosphate-regulated, 3' exonucleolytic mechanism is involved in turnover of yeast mitochondrial RNAs

We have employed cell-free transcription reactions with mitochondria isolated from Saccharomyces cerevisiae to study the mechanism of RNA turnover. The specificity of RNA turnover was preserved in these preparations, as were other RNA-processing reactions, including splicing, 3' end formation of mRNAs, and maturation of rRNAs. Turnover of nascent RNAs was found to occur exonucleolytically; endonucleolytic cleavage products were not detected during turnover of the omega intron RNA, which was studied in detail. However, these experiments still leave open the possibility that endonucleolytic cleavage products with very short half-lives are kinetic intermediates in the decay of omega RNA. Exonucleolytic turnover was regulated by nucleotide triphosphates and required their hydrolysis. A unique signature of this regulation was that any one of the eight standard ribo- or deoxyribonucleotide triphosphates supported RNA turnover. A novel hybrid selection protocol was used to determine the turnover rates of the 5', middle, and 3' portions of one mitochondrial transcript, the omega intron RNA. The results suggested that degradation along that transcript occurred with a 3'-->5' polarity. The similarity between features of mitochondrial RNA turnover and the properties of a nucleotide triphosphate-dependent 3' exoribonuclease that has been purified from yeast mitochondria suggests that this single enzyme is a key activity whose regulation is involved in the specificity of mitochondrial RNA turnover.

Regulation of mitochondrial transcription during the stringent response in yeast

In yeast (S. cerevisiae) the stringent response is known to include rapid, selective, and severe transcriptional curtailment for genes specifying cytoplasmic rRNAs and r-proteins. We have shown that transcription of the mitochondrial 21S rRNA gene is also congruently and selectively curtailed during the yeast stringent response. Using an in vitro transcription assay with intact organelles from both rho+ and rho- strains, we show here that the mitochondrial stringent response includes not only transcription of the 21S and 16S rRNA genes, but also that of organellar genes specifying non-mitoribosome-related products. Stringent organellar transcriptional curtailment is identical when cells are starved for a required (marker) amino acid or when they are subjected to nutritional downshift, and the relative level of that transcriptional curtailment following either perturbation is the same in cells growing on fermentative (repressing) or purely respiratory carbon sources. These results confirm that the mechanism governing mitochondrial gene expression during a stringent response is specified outside the organelle, and they show that this transcriptional control mechanism is not immediately subject to glucose repression. In all strains examined, stringent organellar gene expression requires a mitochondrial promoter, suggesting that the regulatory mechanism which functions during the stringent response operates primarily at transcriptional initiation.

The nuclear SUV3-1 mutation affects a variety of post-transcriptional processes in yeast mitochondria

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.

Structure and transcription of the mitochondrial genome in heteroplasmic strains of Saccharomyces cerevisiae

Saccharomyces cerevisiae strain FF1210-6C/170 is respiratory deficient due to a mutation of the penultimate base of the mitochondrial tRNA(Asp) gene. We have identified a number of progeny from this strain which have reverted to respiratory sufficiency by the excision and tandem amplification of a small region of the mitochondrial (mt) DNA carrying the tRNA(Asp) gene, while also maintaining the full-length mtDNA. We have studied the structure of the mtDNA and mitochondrial transcription in a number of these heteroplasmic strains. The exact site of the recombination involved in the excision of the repeating unit of the amplified mtDNA has been determined for five of the revertants. Recombination occurs between identical sequences 4-13 base pairs in length. Each of the different repeating units of the amplified DNA retains an active promoter which has been moved to a site just upstream of the tRNA(Asp) gene by the excision/amplification. Transcripts from the heteroplasmic strains have been characterized to determine the sites of mitochondrial RNA termini. We find that in addition to the 5' and 3' processing of the tRNAs, many of the transcripts terminate at a position about 300 base pairs downstream of the gene for tRNA(Asp). We also find that 3' processing of tRNA(Asp) precursors is absent in petite strains which lack 5' processing indicating that 5' processing of tRNA(Asp) may be a prerequisite for 3' processing in this mutant.

Mitochondrial rRNA-containing petite strains of yeast (Saccharomyces cerevisiae) show a normal nuclear-mitochondrial stringent response

The nuclear-mitochondrial stringent response was examined in isonuclear rho+, 21S rRNA-containing rho-, and rho o strains of S. cerevisiae. By 30 min after nutritional downshift, nuclear rDNA transcription falls to 15% of control levels congruently in all strains, as assayed via whole-cell RNA or by hybrid selection of specific double-labeled transcripts. Both in vivo and in vitro, the mitochondrial stringent response is identical between the rho- strain and its parental rho+ strain, and in both, the kinetics and magnitude of the organellar response mirror those of the nuclear response. The data show that mitochondrial transcription and protein synthesis are not required for stringent regulation of either nuclear or mitochondrial rDNA transcription.

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

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 micrograms of alpha-amanitin per ml, a concentration that had no effect on rRNA synthesis. Abundant NTS RNAs are therefore most likely derived by polymerase II transcription.

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

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 micrograms of alpha-amanitin per ml, a concentration that had no effect on rRNA synthesis. Abundant NTS RNAs are therefore most likely derived by polymerase II transcription.

A latent intron-encoded maturase is also an endonuclease needed for intron mobility

Some yeast mitochondrial introns encode proteins that promote either splicing (maturases) or intron propagation via gene conversion (the fit1 endonuclease). We surveyed introns in the coxl gene for their ability to engage in gene conversion and found that the group I intron, al4 alpha, was efficiently transmitted to genes lacking it. An endonucleolytic cleavage is detectable in recipient DNA molecules near the site of intron insertion in vivo and in vitro. Conversion is dependent on an intact al4 alpha open reading frame. This intron product is a latent maturase, but these data show that it is also a potent endonuclease involved in recombination. Dual function proteins that cleave DNA and facilitate RNA splicing may have played a pivotal role in the propagation and tolerance of introns.

Nuclear and mitochondrial revertants of a yeast mitochondrial tRNA mutant

We isolated revertants capable of respiration from the respiratory deficient yeast mutant, FF1210-6C/170, which displays greatly decreased mitochondrial protein synthesis due to a single base substitution at the penultimate base of the tRNAAsp gene on mitochondrial (mt) DNA. Three classical types of revertant were identified: (1) same-site revertants; (2) intragenic revertants which restore the base pairing in the acceptor stem of the mitochondrial tRNAAsp; and (3) extragenic suppressors located in nuclear DNA. In addition a fourth type of revertant was identified in which the mutant tRNAAsp is amplified due to the maintenance of both the original mutant mtDNA and a modified form of the mutant mtDNA in which only a small region around the tRNAAsp gene is retained and amplified. The latter form resembles the mtDNA in vegetative petite (rho-) strains which normally segregates rapidly from the wild-type mtDNA. Each revertant type was characterized genetically and by both DNA sequence analysis of the mitochondrial tRNAAsp gene and analysis of the quantity and size of RNA containing the tRNAAsp sequence. These results indicate that the mitochondrial tRNAAsp of the mutant retains a low level of activity and that the presence of the terminal base pair in tRNAAsp is a determinant of both tRNAAsp function and the maintenance of wild-type levels of tRNAAsp.

Identification of a new promoter within the tRNA gene cluster of the mitochondrial DNA of Saccharomyces cerevisiae

We have identified a new promoter within the tRNA gene cluster of Saccharomyces cerevisiae mitochondrial DNA. It is located upstream of the gene encoding the leucyl tRNA. It conforms to the consensus sequence of other yeast mitochondrial promoters, ATATAAGTA. It serves as a site for the initiation of transcription in vivo and in vitro.

Transcription initiation and RNA processing of a yeast mitochondrial tRNA gene cluster

Expression of 5 yeast mitochondrial tRNA genes (Ala, Ile, Tyr, Asn and Metm), localized upstream from the oxil gene has been analyzed by in vitro capping using guanylyltransferase, northern hybridization and S1 nuclease mapping in the wild type and a rho-strain. The 5 tRNA sequences belong to the same transcriptional unit which is initiated 133 bp upstream from the tRNA(Ala) gene at a promoter sequence TTATAAGTA. Furthermore, a truncated tRNA(Tyr) transcript, 2 nucleotides shorter than mature tRNA(Tyr) has been found, only in the rho-strain. This minor transcript may result from secondary transcription initiation at a variant nonanucleotide sequence, ATATAAGGA, which overlaps the tRNA(Tyr) coding sequence by 3 nucleotides. The polycistronic precursor has proven to be useful in investigation of the mechanisms of tRNA processing. Maturation of this primary transcript proceeds exclusively by precise endonucleolytic cleavages at the 5' and 3'-ends of tRNA sequences.

RNA processing and expression of an intron-encoded protein in yeast mitochondria: role of a conserved dodecamer sequence

The 3' ends of most Saccharomyces cerevisiae mitochondrial mRNAs terminate at a conserved dodecamer sequence, 5'-AAUAAUAUUCUU-3', of unknown function. We have studied the consequences of mutations within a dodecamer found in an 1,143-base-pair optional intron of the mitochondrial large (21S) rRNA gene on RNA processing. The dodecamer is situated at the 3' end of an expressed open reading frame (ORF) within that intron, and the mutations are two adjacent transversions that extend the intron ORF by 51 nucleotides. The strain harboring these mutations, L5-10-1, is defective in biased intron transmission in crosses to strains that lack the intron, as are other mutants which contain nucleotide changes within the ORF (I. G. Macreadie, R. M. Scott, A. R. Zinn, and R. A. Butow, Cell 41:395-402, 1985). However, unlike these other mutants, wild-type strains, or petites which retain the intron allele, L5-10-1 is defective in processing at the intron dodecamer. In addition, L5-10-1 lacks a prominent 2.7-kilobase RNA containing both intron and exon sequences and at least two of four RNAs that correspond to various forms of the excised intron. We propose that these RNAs, missing in L5-10-1 but present in all other strains examined, arise in part by processing at the intron dodecamer. In addition, in all strains examined, we have detected a novel processing activity in which precursor 21S rRNA transcripts are cleaved in the upstream exon, about 1,500 nucleotides from the 5' end of the RNA. This activity, together with 3' intron dodecamer cleavage, probably accounts for the 2.7-kilobase RNA species, a candidate for the mRNA for the intron-encoded protein.

RNA processing and expression of an intron-encoded protein in yeast mitochondria: role of a conserved dodecamer sequence

The 3' ends of most Saccharomyces cerevisiae mitochondrial mRNAs terminate at a conserved dodecamer sequence, 5'-AAUAAUAUUCUU-3', of unknown function. We have studied the consequences of mutations within a dodecamer found in an 1,143-base-pair optional intron of the mitochondrial large (21S) rRNA gene on RNA processing. The dodecamer is situated at the 3' end of an expressed open reading frame (ORF) within that intron, and the mutations are two adjacent transversions that extend the intron ORF by 51 nucleotides. The strain harboring these mutations, L5-10-1, is defective in biased intron transmission in crosses to strains that lack the intron, as are other mutants which contain nucleotide changes within the ORF (I. G. Macreadie, R. M. Scott, A. R. Zinn, and R. A. Butow, Cell 41:395-402, 1985). However, unlike these other mutants, wild-type strains, or petites which retain the intron allele, L5-10-1 is defective in processing at the intron dodecamer. In addition, L5-10-1 lacks a prominent 2.7-kilobase RNA containing both intron and exon sequences and at least two of four RNAs that correspond to various forms of the excised intron. We propose that these RNAs, missing in L5-10-1 but present in all other strains examined, arise in part by processing at the intron dodecamer. In addition, in all strains examined, we have detected a novel processing activity in which precursor 21S rRNA transcripts are cleaved in the upstream exon, about 1,500 nucleotides from the 5' end of the RNA. This activity, together with 3' intron dodecamer cleavage, probably accounts for the 2.7-kilobase RNA species, a candidate for the mRNA for the intron-encoded protein.

Sequence and expression of four mutant aspartic acid tRNA genes from the mitochondria of Saccharomyces cerevisiae

Expression of the mitochondrial tRNAAsp gene of Saccharomyces cerevisiae has been examined in five syn- mutants known to affect tRNAAsp function, and in a rho- mutant which accumulates precursor tRNAs. By comparison of wild-type versus mutant DNA sequence, the lesion in each syn- mutant has been identified as a single base change within the mitochondrial tRNAAsp structural gene. The mutant tRNAAsp genes are transcribed, and the transcripts can be processed to mature 4S-size tRNAAsp. The steady-state level of each mutant tRNAAsp is lower than that of wild-type tRNAAsp. The RNA from two of the syn- mutants contained a second, slow-migrating form of mitochondrial tRNAAsp which is correctly processed at the 5' end. We conclude that the lesions in the syn- mitochondrial tRNAAsp genes block neither transcription of these genes, nor 5'-end processing of the transcripts. The effect of each point mutation must be manifested at the level of 3'-end processing, or at a functional level.

Splicing of large ribosomal precursor RNA and processing of intron RNA in yeast mitochondria

We have studied splicing of precursors to the large ribosomal RNA and processing of the excised intron in yeast mitochondria using primer extension with reverse transcriptase and electron microscopy. Structural features of the following intermediates are described: first, a linear RNA carrying a 5'-terminal G that is not encoded in mitochondrial DNA; second, a circular RNA in which the 3' and 5' intron borders are covalently linked. Three nucleotides of the 5' intron border are absent from the site of circle closure. The properties of these intermediates fit remarkably well into the mechanism of self-splicing described for the ribosomal precursor RNA from Tetrahymena nuclei. A new feature of the yeast mitochondrial system is that the excised intron can have one of two destinies, circularization or cleavage at an internal position.

Initiation of transcription of a mitochondrial tRNA gene cluster in S. cerevisiae

In Saccharomyces cerevisiae most mitochondrial tRNA genes are clustered in a 9 kbp region between the cap and oxil genes. Polygenic transcripts of this region have been previously identified. A transcriptional initiation site at a TTATAAGTA box, located upstream from the tRNAcys gene, has now been detected by S1 mapping experiments and by the capping of primary transcripts. Results are consistent with the hypothesis that this box represents the initiation site for transcription of a cluster of tRNA genes, while the adjacent tRNA2thr is cotranscribed with the 21S rRNA. Results obtained with various strains are compared, and the efficiency of this sequence as a transcriptional initiation site in different mitochondrial contexts is discussed.

Organization and processing of the mitochondrial oxi3/oli2 multigenic transcript in yeast

In the present article, we confirm our previous proposal (Faye and Simon 1983a, b) that the oxi3 and oli2 genes belong to the same transcription unit. Furthermore, we have shown that a primary polycistronic transcript covers oxi3, aap1, oli2 and extends beyond URF2. Transcriptional analysis of this region revealed several cleavage points. The examination of the DNA sequence at and surrounding these cleavage points disclosed that some of them take place at or near specific sequences found also in other known multigenic transcripts. Two of the major cleavages involve the stem-loop structure of GC rich clusters. We discuss the possibility that some of these cleavage sites serve as post-transcriptional processing signals and may be necessary for the maturation of the precursor RNA.

Initiation of transcription in yeast mitochondria: analysis of origins of replication and of genes coding for a messenger RNA and a transfer RNA

The initiation of transcription of the yeast mitochondrial genes coding for subunit I of cytochrome c oxidase (COX1) and for tRNA1Thr has been examined. COX1 messenger RNA synthesis is initiated in a conserved nonanucleotide sequence (ATATAAGTA) which we have previously found immediately upstream of ribosomal RNA genes at positions at which RNA synthesis starts. The 5'-end of the precursor of tRNA1Thr is located in a variant nonanucleotide motif (TTATAAGTA), which may be characteristic for tRNA genes. Using a partially purified fraction of mtRNA polymerase, we demonstrate that RNA synthesis is precisely initiated in vitro in nonanucleotide sequences preceding both ribosomal RNA-, tRNA- and messenger RNA-encoding genes and origins of replication.

Transcriptional analysis of the Saccharomyces cerevisiae mitochondrial var1 gene: anomalous hybridization of RNA from AT-rich regions

A family of mitochondrial RNAs hybridizes specifically to the var1 region on Saccharomyces cerevisiae mitochondrial DNA (Farrelly et al., J. Biol. Chem. 257:6581-6587, 1982). We constructed a fine-structure transcription map of this region by hybridizing DNA probes containing different portions of the var1 region and some flanking sequences to mitochondrial RNAs isolated from var1-containing petites. We also report the nucleotide sequence of more than 1.2 kilobases of DNA flanking the var1 gene. Our primary findings are: (i) The family of RNAs we detect with homology to var1 DNA is colinear with the var1 gene. Their direction of transcription is olil to cap, as it is for most other mitochondrial genes. (ii) Extensive hybridization anomalies are present, most likely due to the high A-T (A-U) content of the hybridizing species and to the asymmetric distribution of their G-C residues. An important conclusion is that failure to detect transcripts from A-T-rich regions of the yeast mitochondrial genome by standard blot transfer hybridizations cannot be interpreted to mean that such sequences, which are commonly supposed to be spacer DNA, are noncoding or lack direct function in the expression of mitochondrial genes.

Initiation of transcription of the yeast mitochondrial gene coding for ATPase subunit 9

We have determined transcriptional initiation sites for the ATPase subunit 9 gene on the yeast mitochondrial genome. Using S1 nuclease mapping, in vitro capping of primary transcripts with GTP and guanylyl transferase, and in vitro transcription analysis with purified mitochondrial RNA polymerase, we find the major site of transcriptional initiation to be at a point 630 nucleotides upstream of the coding region for the gene. In addition, we find much lower levels of initiation at a second site 78 nucleotides downstream of the first. Both initiation sites occur at the same position within a nonanucleotide sequence which we have previously found associated with initiation of rRNA synthesis. This work further supports the notion that this nonanucleotide sequence is an integral component of mitochondrial promoters and indicates that the same RNA polymerase is used for transcription of both mRNA and rRNA in yeast mitochondria.

Transcriptional analysis of the Saccharomyces cerevisiae mitochondrial var1 gene: anomalous hybridization of RNA from AT-rich regions

A family of mitochondrial RNAs hybridizes specifically to the var1 region on Saccharomyces cerevisiae mitochondrial DNA (Farrelly et al., J. Biol. Chem. 257:6581-6587, 1982). We constructed a fine-structure transcription map of this region by hybridizing DNA probes containing different portions of the var1 region and some flanking sequences to mitochondrial RNAs isolated from var1-containing petites. We also report the nucleotide sequence of more than 1.2 kilobases of DNA flanking the var1 gene. Our primary findings are: (i) The family of RNAs we detect with homology to var1 DNA is colinear with the var1 gene. Their direction of transcription is olil to cap, as it is for most other mitochondrial genes. (ii) Extensive hybridization anomalies are present, most likely due to the high A-T (A-U) content of the hybridizing species and to the asymmetric distribution of their G-C residues. An important conclusion is that failure to detect transcripts from A-T-rich regions of the yeast mitochondrial genome by standard blot transfer hybridizations cannot be interpreted to mean that such sequences, which are commonly supposed to be spacer DNA, are noncoding or lack direct function in the expression of mitochondrial genes.

Identification of a single transcriptional initiation site for the glutamic tRNA and COB genes in yeast mitochondria

We have identified a single transcriptional initiation site for the glutamic tRNA and COB (cytochrome b) genes by using the complementary techniques of in vitro capping of RNA and in vitro transcription. In the capping reaction, mitochondrial RNA is labeled with [alpha-32P]GTP by vaccinia virus guanylyltransferase. This reaction is specific for the 5' ends of RNA retaining the terminal triphosphate of transcriptional initiation. Exploiting the extremely low G+C content (18%) of yeast mitochondrial DNA, we digested in vitro capped transcripts from various petite deletion mutants with the G-specific RNase T1. By petite deletion mapping, a capped transcript giving rise to a 51-base RNase T1-generated oligonucleotide was localized near the glutamic tRNA gene. When the sequence of this oligonucleotide was determined, it perfectly matched the DNA sequence 391 base upstream of the glutamic tRNA. Purified yeast mitochondrial RNA polymerase initiated transcription in vitro at the same site as shown by the sequence of the 33-base oligonucleotide product of the reaction performed in the absence of CTP. Initiation starts at a nonanucleotide sequence previously implicated in yeast mitochondrial transcriptional initiation. Because there is no evidence of an initiation site in the 1,050 bases between the glutamic tRNA and COB genes, the two genes are likely to be transcribed together. Further evidence of a long common transcript was provided by RNA blot hybridization.

Site-specific relaxation and recombination by the Tn3 resolvase: recognition of the DNA path between oriented res sites

We studied the dynamics of site-specific recombination by the resolvase encoded by the Escherichia coli transposon Tn3. The pure enzyme recombined supercoiled plasmids containing two directly repeated recombination sites, called res sites. Resolvase is the first strictly site-specific topoisomerase. It relaxed only plasmids containing directly repeated res sites; substrates with zero, one or two inverted sites were inert. Even when the proximity of res sites was ensured by catenation of plasmids with a single site, neither relaxation nor recombination occurred. The two circular products of recombination were catenanes interlinked only once. These properties of resolvase require that the path of the DNA between res sites be clearly defined and that strand exchange occur with a unique geometry. A model in which one subunit of a dimeric resolvase is bound at one res site, while the other searches along adjacent DNA until it encounters the second site, would account for the ability of resolvase to distinguish intramolecular from intermolecular sites, to sense the relative orientation of sites and to produce singly interlinked catenanes. Because resolvase is a type 1 topoisomerase, we infer that it makes the required duplex bDNA breaks of recombination one strand at a time.