Pleiotropic mutations within two yeast mitochondrial cytochrome genes block mRNA processing

Modular assembly of yeast mitochondrial ATP synthase and cytochrome oxidase

The respiratory pathway of mitochondria is composed of four electron transfer complexes and the ATP synthase. In this article, we review evidence from studies of Saccharomyces cerevisiae that both ATP synthase and cytochrome oxidase (COX) are assembled from independent modules that correspond to structurally and functionally identifiable components of each complex. Biogenesis of the respiratory chain requires a coordinate and balanced expression of gene products that become partner subunits of the same complex, but are encoded in the two physically separated genomes. Current evidence indicates that synthesis of two key mitochondrial encoded subunits of ATP synthase is regulated by the F1 module. Expression of COX1 that codes for a subunit of the COX catalytic core is also regulated by a mechanism that restricts synthesis of this subunit to the availability of a nuclear-encoded translational activator. The respiratory chain must maintain a fixed stoichiometry of the component enzyme complexes during cell growth. We propose that high-molecular-weight complexes composed of Cox6, a subunit of COX, and of the Atp9 subunit of ATP synthase play a key role in establishing the ratio of the two complexes during their assembly.

Human Mitochondrial Pathologies of the Respiratory Chain and ATP Synthase: Contributions from Studies of Saccharomyces cerevisiae

The ease with which the unicellular yeast Saccharomyces cerevisiae can be manipulated genetically and biochemically has established this organism as a good model for the study of human mitochondrial diseases. The combined use of biochemical and molecular genetic tools has been instrumental in elucidating the functions of numerous yeast nuclear gene products with human homologs that affect a large number of metabolic and biological processes, including those housed in mitochondria. These include structural and catalytic subunits of enzymes and protein factors that impinge on the biogenesis of the respiratory chain. This article will review what is currently known about the genetics and clinical phenotypes of mitochondrial diseases of the respiratory chain and ATP synthase, with special emphasis on the contribution of information gained from pet mutants with mutations in nuclear genes that impair mitochondrial respiration. Our intent is to provide the yeast mitochondrial specialist with basic knowledge of human mitochondrial pathologies and the human specialist with information on how genes that directly and indirectly affect respiration were identified and characterized in yeast.

Protein encoded by the third intron of cytochrome b gene in Saccharomyces cerevisiae is an mRNA maturase. Analysis of mitochondrial mutants, RNA transcripts proteins and evolutionary relationships

We have established the nucleotide sequence of the wild-type and that of a trans-acting mutant located in the third (bi3) intron of the Saccharomyces cerevisiae mitochondrial cytochrome b gene. The intron, 1691 base-pairs long, has an open reading frame 1045 base-pairs long, in phase with the preceding exon and the mutation replaces the evolutionarily conserved Gly codon of the second consensus motif by an Asp codon and blocks the formation of mature cytochrome b mRNA. Splicing intermediates of 5300 and 3900 bases with unexcised bi3 intron and a characteristic novel polypeptide (p50), the size of which corresponds to the chimeric protein encoded by upstream exons and the bi3 intronic open reading frame (ORF), accumulate in this and other bi3 splicing-deficient mutants. We conclude that the protein encoded by the bi3 ORF is a specific mRNA maturase involved in the splicing of the cytochrome b mRNA. The open reading frame of the third intron is remarkably similar to that of the unique intron of the cytochrome b gene (cob A) of Aspergillus nidulans. Both are located in exactly the same position and possibly derive from a recent common ancestor by a horizontal transfer. We have established the nucleotide sequence of an exonic mutant located in the B3 exon. This missense mutation changes the Phe codon 151 into a Cys codon and leads to the absence of functional cytochrome b but does not affect splicing. Finally, we have studied the splicing pathway leading to the synthesis of cytochrome b mRNA by analysing, in a comprehensive manner, the 22 splicing intermediates of several mutants located in bi3.

RNA splicing in yeast mitochondria: DNA sequence analysis of mit- mutants deficient in the excision of introns aI1 and aI2 of the gene for subunit I of cytochrome c oxidase

We have characterized two yeast mutants deficient in the splicing of transcripts of the mitochondrial gene for cytochrome c oxidase subunit I (coxI). Both map to the first intron (aI1). RNA blot analysis shows that in addition to a reduced (mutant M15-190) or blocked (mutant M12-193) excision of the mutated intron aI1, the mutants are unable to excise the adjacent aI2 intron, the reading frame of which displays an amino acid sequence similarity to aI1. Splicing of the downstream introns is not affected, however. Sequence analysis of the first mutant DNA (M12-193) reveals a premature termination of the intron-encoded open reading frame, followed by two alterations at a short distance downstream. The other (M15-190) contains 11 separate changes. Although these occur in the intron reading frame, their main effect on RNA splicing may be exerted through the disturbance of intron secondary structure proposed for the 5' end of several group II introns. The implications of these findings in relation to maturase function and structure of intron aI1 are discussed.

Introns as relict retrotransposons: implications for the evolutionary origin of eukaryotic mRNA splicing mechanisms

A model is presented for the evolutionary origin of intron sequences within eukaryotic protein-coding genes. We propose that introns are the vestiges of transposable elements and, specifically, that they represent a novel class of retrovirus-like transposons. The attraction of the retrotransposon model is that it gives the RNA splicing mechanism a central role in the evolution of introns. There is a growing body of evidence to suggest that several aspects of splicing are intron-encoded. Consequently, it is reasonable to look for evolutionary explanations of the splicing mechanism in the context of the evolution of the intron sequences themselves. According to this model the ancestral intron genomes were replicated into RNA copies simply because of their insertion within transcriptionally active regions of the host genome. Splicing was necessary not only to minimize their negative effects on host gene expression, but also, and perhaps more importantly, to generate new copies of the intron genome free of flanking exon sequences. These spliced intron copies were then available for reverse transcription and reinsertion elsewhere in the genome. Thus, splicing can be seen as an essential step in the intron replication cycle. Most modern introns have probably lost the majority of their original genetic content and may be considered as degenerate evolutionary relicts. An exception to this degeneracy is the set of splicing signals which must be retained because of its continued importance to host cell survival.(ABSTRACT TRUNCATED AT 250 WORDS)

Control of cell growth and division in Saccharomyces cerevisiae

Considerable advances have been made in recent years in our understanding of the biochemistry of protein and nucleic acid synthesis and, particularly, the molecular biology of gene expression in eukaryotes. The yeast Saccharomyces cerevisiae, and to a lesser extent Schizosaccharomyces pombe, has had a preeminent role as a focus for these studies, principally because of the facility with which these organisms can be experimentally manipulated biochemically and genetically. This review will be designed to critically examine and integrate recent advances in several vital areas of regulatory control of enzyme synthesis in yeast: structure and organization of DNA, transcriptional regulation, post-transcriptional modification, control of translation, post-translational modification and secretion, and cell-cycle modulation. It will attempt to emphasize and illustrate, where detailed information is available, principal underlying molecular mechanisms, and it will attempt to make relevant comparisons of this material to inferred and demonstrated facets of regulatory control of enzyme and protein synthesis in higher eukaryotes.

Leakiness of termination codons in mitochondrial mutants of the yeast Saccharomyces cerevisiae

Seven mutants in exon 1 of the mitochondrial cob gene in yeast are described with respect to their translation products, RNA pattern, and deoxyribonucleotide sequence alteration(s). Sequence analysis of the mutations, which previously were shown to cause premature termination of apocytochrome b, revealed that two of them directly transform sense codons to chain-termination codons, whereas the other four are frame-shift mutations (+1/-1, insertions/deletions). Only the latter mutants are found to be leaky in that (a) RNA splicing occurs, and (b) in three of them, to a minor degree an apocytochrome b homologue is synthesized, which, however, does not lead to respiratory competence. Both require translation through exon 1 into downstream introns to produce 'RNA maturases' necessary for splicing the primary transcript (Lazowska et al. 1980; Weiss-Brummer et al. 1982). These and other previously published data show that mitochondrial frame-shift mutants tend to be leaky to a variable degree. Several possible mechanisms of 'frame-shift suppression' are discussed.

Yeast mitochondria contain a linear RNA strand complementary to the circular intronic bI1 RNA of cytochrome b

bI1 RNA (excised from the first intron of the long form of the cytochrome b gene of Saccharomyces cerevisiae mitochondria) hybridizes with the two strands of a Bg/II-MboI DNA segment from this region. This fraction is resistant to digestions by DNase I and RNase T1 and disappears completely upon alkali hydrolysis. Strand-specific labeling of an intronic DNA fragment, cloned in pBR322 plasmid, was accomplished through the use of a T4 DNA polymerase. The purity of the probes was demonstrated by cloning an exon-intron fragment and labeling it by the same procedure; mRNA and pre-mRNA bands hybridized only with the transcribed DNA strand whereas bI1 RNA hybridized with the two strands under the stringent washing conditions employed (tm + 20 degrees C). Several experimental results argue against the possibility that the observation of two complementary bI1 RNA strands results from a partial self-complementarity of the RNA. A pre-mRNA intermediate from a box8 (G5046) mutant, still containing this intron, hybridizes only with the transcribed DNA strand of the pure intronic probe. The amount of the non-sense bI1 RNA strand is very low, in cells from two wild-type strains, relative to the sense RNA strand during the early stages of growth on glucose. It increases as the cells are released from glucose repression. bI1 RNA is resistant to RNase. Very little self-complementarity is seen by computer analysis of the sequence. Purified bI1 RNA is seen by electron microscopy under non-denaturing conditions as a mixture of double-stranded circular and linear molecules thus confirming the existence of the two complementary strands. The disappearance of all material following alkali hydrolysis demonstrates that these are indeed two RNA strands. Under fully denaturing conditions a mixture of single-stranded circular and linear molecules is seen as reported previously (Cell, 19, 321-329, 1980). We conclude that yeast mitochondria contain the two complementary bI1 RNA strands, one circular and the other linear. Considering a largely asymmetrical transcription of the mitochondrial genome in yeast and assuming that circularization of some intronic RNAs is part of RNA processing, we do not believe that the two strands are each a mixture of linear and circular molecules. The ratio of non-sense to sense bI1 RNA in a cytoplasmic petite mutant, A1B1, also varies according to growth conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

Molecular basis of the 'box effect', A maturase deficiency leading to the absence of splicing of two introns located in two split genes of yeast mitochondrial DNA

In the mitochondrial DNA of Saccharomyces cerevisiae, the genes cob-box and oxi3, coding for apocytochrome b and cytochrome oxidase subunit I respectively, are split. Several mutations located in the introns of the cob-box gene prevent the synthesis of cytochrome b and cytochrome oxidase subunit I (this is known as the 'box effect').-We have elucidated the molecular basis of this phenomenon: these mutants are unable to excise the fourth intron of oxi3 from the cytochrome oxidase subunit I pre-mRNA; the absence of a functional bI4 mRNA maturase, a trans-acting factor encoded by the fourth intron of the cob-box gene explains this phenomenon. This maturase was already known to control the excision of the bI4 intron; consequently we have demonstrated that it is necessary for the processing of two introns located in two different genes. Mutations altering this maturase can be corrected, but only partially, by extragenic suppressors located in the mitochondrial (mim2) or in the nuclear (NAM2) genome. The gene product of these two suppressors should, therefore, control (directly or indirectly) the excision of the two introns as the bI4 mRNA maturase normally does.

Interaction between mitochondrial genes in yeast: evidence for novel box effect(s)

The effects of mutations have been studied within the apocytochrome b gene on the processing of transcripts from the gene for subunit 1 of cytochrome c oxidase (coxI). Most mutations which affect the expression of the reading frame encoded by the fourth intron of the apocytochrome b gene (bI4) result in a failure to remove intron aI4 from precursor transcripts of coxI. Mutations in other apocytochrome b introns result in additional and complex defects in the processing of subunit I transcripts. Mutants M1233 and M1282 are mutated within the second intron (bI2) of the apocytochrome b gene and have OXI3 transcripts of 4900, 6100, and 6500 nucleotides. These transcripts are absent from the wild-type strain and do not hybridize with all exon sequences of this gene. In mutant M1392 (mutated within the third intron of the apocytochrome b gene), two OXI3 transcripts of 2200 and 2800 nucleotides are present which hybridize only with sequences downstream of the fifth exon of this gene (A5 alpha). We propose that all these transcripts result from distinctive cut-no-splice events, occurring at different intron-exon borders of OXI3 pre-RNAs depending on the mutational site within the apocytochrome b gene. The box9 mutant M4458 and the box7 mutant M1431 lack detectable 18S mRNA for subunit I of cytochrome c oxidase. The box9 mutants M4751 and M4701 contain reduced amounts of this mRNA. The fact that these loci complement each other (B. Weiss-Brummer, G. Rödel, R.J. Schweyen, and F. Kaudewitz (1982) Cell 29, 527-536), therefore, suggests that mutations within the different functional domains of bI4 lead to different defects in the processing of OXI3 transcripts. This, together with the defects observed in bI2 and bI3 mutants, implies that the box effect (i.e., the interaction between these two split genes) is not mediated by the box7 element alone. The possibility is discussed that mutated apocytochrome b intronic reading frame products lead to these aberrant events in the processing of transcripts of the gene for subunit I of cytochrome c oxidase.

The intron of the mitochondrial 21S rRNA gene: distribution in different yeast species and sequence comparison between Kluyveromyces thermotolerans and Saccharomyces cerevisiae

We have screened numerous different yeast species for the presence of sequences homologous to the intron of the mitochondrial 21S rRNA gene of Saccharomyces cerevisiae (intron r1) and found them in all Kluyveromyces species, some of the Saccharomyces species and none of the other yeasts tested. We have determined the nucleotide sequence of the r1-intron in K. thermotolerans and compared it with that of S. cerevisiae. The two introns are inserted at the same position within the 21S rRNA gene. They contain homologous internal open reading frames (ORFs) initiated at the same AUG codon which can be aligned over their entire length. Several silent multi-substitutions indicate that these intronic ORFs represent selectively conserved functional genes. Other intron segments, on the contrary, reveal short blocks of extensive homology separated by non-homologous stretches and/or additions-deletions. Comparison of our two yeast r1-introns with equivalent introns of N. crassa and A. nidulans mitochondria reveals that introns with very similar RNA secondary structures can accommodate different types of ORFs.

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.

Processing of yeast mitochondrial RNA: involvement of intramolecular hybrids in splicing of cob intron 4 RNA by mutation and reversion

Revertants have been obtained from six mutants of the box9 cluster, which are supposed to be defective in RNA splicing as a result of alterations in a splice signal sequence. This sequence is in the 5' part of intron 4 of the cob gene, 330 to 340 bp downstream from the 5' splice site. Sequencing reveals that reversion to splicing competence is achieved by restoration of the wild-type box9 sequence; by creation of novel box9 sequences; and by introduction of a second site or suppressor mutation (sup-) compensating for the effect of the primary box9- mutation. The sup- mutation alters a sequence in intron 4,293 bp upstream from the box9- primary mutation. The box9 sequence and this upstream sequence can base pair to form an intramolecular hybrid in intron RNA in which box9- and sup- are compensatory base pair exchanges (G----A and C----U, respectively). Thus intramolecular hybrid structures of intron RNA are essential for RNA splicing.

Mitochondrial circular RNAs are absent in sporulating cells of Saccharomyces cerevisiae

During sporulation of Saccharomyces cerevisiae the mitochondria undergo a differentiation process, leading to a "spore mitochondrion", which differs both physiologically and morphologically from vegetative cell mitochondria. We report here the behaviour of the mitochondrial transcripts during this differentiation process. The circular transcripts representing spliced introns of the two mitochondrial split genes for cytochrome b and for the subunit 1 of the cytochrome c oxidase, which are very abundant during vegetative growth, are not detectable in sporulating cells. This loss does neither take place in haploid cells under sporulation conditions nor when erythromycin is added to the medium. The process of some mRNAs is advanced in relation to their precursors in sporulating cells.

Mitochondrial translation products during release from glucose repression in Saccharomyces cerevisiae

Mitochondrial protein synthesis was studied during release from glucose repression in Saccharomyces cerevisiae cells bearing different mitochondrial genomes. The increase in the rate of the synthesis of mitochondrial translation products was analyzed during respiratory induction. Different kinetic patterns were found for strains having a different structure of mitochondrial mosaic genes, even when the nuclear background was the same. A very limited response of the synthesis of the var1 ribosomal protein to inducing conditions was observed.

Variation, transcription and circular RNAs of the mitochondrial gene for subunit I of cytochrome c oxidase

The gene for subunit I of cytochrome c oxidase, contained within the OX13 region of yeast mitochondrial DNA, is split and shows a remarkable variation in structure, which is strain-dependent. The most complex form so far characterized is that of the Saccharomyces cerevisiae strain KL14-4A, in which nine or possibly ten exons are separated by eight to nine introns. At least four of these are facultative, two being absent from S. cerevisiae strain D273-10B (sequenced by Bonitz et al., 1980) and a further two lacking from the gene in Saccharomyces carlsbergensis. The complexity of the gene in KL14-4A is also reflected in its transcript pattern. RNA blot hybridization with isolated and cloned DNA fragments of the OX13 region permits visualization of more than 60 RNAs, which show overlapping and discontinuous hybridization behaviour. In the less complex strains D273-10B and S. carlsbergensis, this number is 20 and 11, respectively. These RNAs are most likely intermediates in processing events leading to the appearance of the mature messenger RNA for cytochrome c oxidase subunit I, which we identify as a 2100-nucleotide transcript (18SE). Most of the processing events are dependent on mitochondrial protein synthesis and do not constitute a single obligatory processing pathway. Like other yeast mitochondrial mRNAs, the 18 S RNA contains a long, untranslated 5' flanking sequence (approximately 400 nucleotides). One unusual aspect of splicing events involving OX13 transcripts is the accumulation of three of the excised introns as single-stranded RNA circles. These abundant and stable transcripts appear to be covalently closed. The simplest assumption is that they arise as (by)-products of splicing, but secondary ligation events have not been excluded. Their function is as yet unknown.

Two intron sequences in yeast mitochondrial COX1 gene: homology among URF-containing introns and strain-dependent variation in flanking exons

The DNA sequences of two optional introns in the gene for subunit I of cytochome c oxidase in yeast mitochondrial DNA have been determined. Both contain long unassigned reading frames (URFs). These display regions of amino acid homology with six other URFs, two of which encode proteins involved in mitochondrial RNA splicing. Such conserved regions may thus define functionally important domains of proteins involved in RNA processing. This homology also implies that these URFs had a common ancestral sequence, which has been duplicated and dispersed around the genome. Comparison of the flanking exons in the long strain KL14-4A with their unsplit counterpart in D273-10B reveals clustered sequence differences, which lead in D273-10B to codons rarely used in exons. These differences may be linked to the loss or absence of one of the optional introns.

Transcription of mitochondrial DNA

While mitochondrial DNA (mtDNA) is the simplest DNA in nature, coding for rRNAs and tRNAs, results of DNA sequence, and transcript analysis have demonstrated that both the synthesis and processing of mitochondrial RNAs involve remarkably intricate events. At one extreme, genes in animal mtDNAs are tightly packed, both DNA strands are completely transcribed (symmetric transcription), and the appearance of specific mRNAs is entirely dependent on processing at sites signalled by the sequences of the tRNAs, which abut virtually every gene. At the other extreme, gene organization in yeast (Saccharomyces) is anything but compact, with long stretches of AT-rich DNA interspaced between coding sequences and no obvious logic to the order of genes. Transcription is asymmetric and several RNAs are initiated de novo. Nevertheless, extensive RNA processing occurs due largely to the presence of split genes. RNA splicing is complex, is controlled by both mitochondrial and nuclear genes, and in some cases is accompanied by the formation of RNAs that behave as covalently closed circles. The present article reviews current knowledge of mitochondrial transcription and RNA processing in relation to possible mechanisms for the regulation of mitochondrial gene expression.

Oligoadenylate is present in the mitochondrial RNA of Saccharomyces cerevisiae

We examined Saccharomyces cerevisiae mitochondrial RNA for polyadenylate. Using hybridization to [3H]polyuridylate as the assay for adenylate sequences, we found adenylate-rich oligonucleotides approximately 8 residues long. Longer polyadenylate was not detected. Most of the adenylate-rich sequence is associated with the large mitochondrial rRNA. The remainder is associated with the 10-12S group of transcripts.

Functional domains in introns: trans-acting and cis-acting regions of intron 4 of the cob gene

We have sequenced the mutational changes in eight mutants in the open reading frame of intron 4 of the cob gene on yeast mitochondrial DNA. Three have a cis-acting splicing defect, while the other inactivate a trans-recessive intron domain that specifies a trans-acting splicing factor. From phenotypic evidence, including analyses of the allele-specific extra proteins, we have identified a protein (P27) encoded wholly within the intron that appears to be the intron 4 splicing factor (maturase). The evidence suggests that P27 is a secondary translation product resulting from the proteolytic cleavage of a larger precursor encoded by exon and intron sequences, but an alternative model, in which P27 is a primary translation product, has not been ruled out.

Single base substitution in an intron of oxidase gene compensates splicing defects of the cytochrome b gene

An extragenic suppressor mutation, mim2-1, which compensates yeast mitochondrial mutants deficient in splicing of the cytochrome b gene, has been mapped and sequenced. The mutation is due to a single G leads to A transition in the long open reading frame of the fourth intron of the oxidase subunit one gene. It causes the replacement of a glutamic codon by a lysine codon and the expression of a novel mRNA maturase active in splicing. Evolution and regulatory connections between homologous introns of nonhomologous genes are discussed.

RNA splicing in Neurospora mitochondria. Characterization of new nuclear mutants with defects in splicing the mitochondrial large rRNA

In Neurospora, the gene encoding the mitochondrial large (25S) ribosomal RNA contains an intervening sequence of 2.3 kb. We have identified eight nuclear mutants that are defective in splicing the mitochondrial large ribosomal RNA and that accumulate unspliced precursor RNA. These mutants identify three different nuclear genes required for the same mitochondrial RNA splicing reaction. Some of the mutants have unique phenotypic characteristics (for example, accumulation of an unusual intron RNA) that may provide insight into specific aspects of mitochondrial RNA splicing. Mutations at one locus, cyt4, are subject to partial phenotypic suppression by the electron-transport inhibitor antimycin. This phenomenon suggests that at least one component required for mitochondrial RNA splicing is regulated such that its synthesis or activity is increased in response to impairment of electron transport.

Expression of the split gene cob in yeast: evidence for a precursor of a "maturase" protein translated from intron 4 and preceding exons

Intron 4 (14) of the split gene cob in mitochondrial DNA contains a long open reading frame in phase with the preceding exon. Mutations in this intron block the excision of the 14 sequence from the cob precursor RNA and, at the same time, generate a series of new polypeptides, parts of which apparently result from translation of 14 sequences. We sequenced six mutations clustered in the upstream part of the open reading frame, about 340 bp from the exon-intron boundary (box9 cluster). Four are base pair exchanges in the same triplet of this region; these form the polypeptides typical for 14 plus a trans-acting product encoded by 14, as shown by complementation studies. The other two mutations--a -2 bp deletion at the same site, causing frameshift with a chain-terminating codon within a few triplets, and a base pair exchange at a nearby site--affect both the formation of 14 typical translation products and the trans-acting function. These results on box9 mutants combined with results on box7 mutants suggest that an 14-encoded "maturase" protein (apparent molecular weight, 27,000) is cleaved off a precursor protein (apparent molecular weight, 55,000) encoded by exon sequences B1 to B4 and the intron open reading frame. We further discuss the role of the box9 nucleotide sequence in the maturation of cob-specific RNA.

Critical sequences within mitochondrial introns: pleiotropic mRNA maturase and cis-dominant signals of the box intron controlling reductase and oxidase

We have established the DNA sequence of nine yeast mutants that prevent the expression either of the split cytochrome b gene alone (five mutants) or of two split genes, the cytochrome b gene and the cytochrome oxidase subunit I gene (four mutants). All the mutations analyzed are localized in intron 14 of the cob-box gene. We have extended the concept of the intron-encoded mRNA maturase, already described for intron 12, to the intron 14, and have adduced evidence that this box7 pleiotropic maturase is involved in the splicing of two distant gene transcripts. Such a process may constitute a regulatory mechanism that coordinates the expression of two structurally nonhomologous genes encoding two metabolically related enzymes. Analyses of cis-dominant mutations reveal the role of signal sequences in the recognition of the intron RNA sequences to be excised. These signal sequences are localized near the exon-intron boundaries (box1), or quite distant from the splicing sites, either in the blocked reading frame (box2) or in the open reading frame (box9) of the intron. We believe that for the last sequence, a ribosomal recognition of the box9 signal could be involved in a regulatory mechanism of the splicing of the pre-mRNA.

Critical sequences within mitochondrial introns: cis-dominant mutations of the "cytochrome-b-like" intron of the oxidase gene

We have established the DNA sequence of two cis-dominant mutations located in the fourth intron, a14, of the yeast mitochondrial gene oxi3. These mutations prevent the synthesis of subunit I of cytochrome oxidase. Both mutations affect a very short DNA sequence located several hundred base pairs from the intron-exon junctions. An identical sequence is found in the cob-box gene; and this sequence is critical for the excision of the cytochrome b intron. Our interpretation is that this short sequence represents a common signal that must be recognized by the box7-encoded mRNA maturase, in conjunction with the mitochondrial ribosome, to splice out the introns in the two nonhomologous genes, cob-box and oxi3.

Oligoadenylate is present in the mitochondrial RNA of Saccharomyces cerevisiae

We examined Saccharomyces cerevisiae mitochondrial RNA for polyadenylate. Using hybridization to [3H]polyuridylate as the assay for adenylate sequences, we found adenylate-rich oligonucleotides approximately 8 residues long. Longer polyadenylate was not detected. Most of the adenylate-rich sequence is associated with the large mitochondrial rRNA. The remainder is associated with the 10-12S group of transcripts.

A novel species of double stranded RNA in mitochondria of Saccharomyces cerevisiae

A double stranded RNA species has been detected in guanidine hydrochloride extracts of mitochondria from respiratory competent cells of Saccharomyces cerevisiae. This novel mitochondrial RNA, termed mtdsRNA, has been purified in a Cs2SO4 density gradient where it bands at a density of 1.58 g/ml. The mtdsRNA runs as a single slow moving band on agarose gels. Its double stranded RNA character was evidenced by its sensitivity to digestion by RNase III, but not by RNase H, or DNase I. Moreover the mtdsRNA hybridized to each separated strand of a petite mtDNA. It is concluded that mtdsRNA contains long transcripts derived from most regions of yeast mtDNA, because 1) its weight-average length as determined by electron microscopy was 4.5 micrometer (about 14 kb, or 20% of the wild type mtDNA genome), and 2) it hybridized to each of a series of eight petite mtDNA probes carrying sequences derived from widely different segments of mtDNA. It is proposed that prolonged transcription of both strands of yeast mtDNA can occur and that mtdsRNA arises from hybridization of these long complementary transcripts.

Evidence for ribosomes involved in splicing of yeast mitochondrial transcripts

We have investigated the processing of transcripts of the split gene COB in yeast mitochondrial DNA from cells whose mitochondrial translation was blocked by chloramphenicol for several generations of cell growth. First analysis of transcripts by electrophoresis and RNA/DNA-hybridization clearly showed that cell growth in the presence of CAP leads to an inhibition of processing yielding an increasing amount of splicing intermediates of the COB transcript and decreasing amounts of the 18S mRNA coding for apocytochrome b. This observation is in accordance with the now widely favoured idea that mitochondrial proteins are involved in splicing of COB transcripts and that their reduction should hamper processing and - therefore - lead to an accumulation of pre-mRNAs. However, further information obtained by pulse-labeling of pre-mRNA in vivo in the presence of CAP for various times shows that even 30 minutes after addition of CAP a reduction of the processing rate is obtained. Based on these findings we conclude that maturation of mtRNAs is not only dependent on mitochondrial proteins, but also on a more direct interaction of the translation machinery and RNA processing whose nature is so far unknown.

Long range control circuits within mitochondria and between nucleus and mitochondria. II. Genetic and biochemical analyses of suppressors which selectively alleviate the mitochondrial intron mutations

In the preceding paper of this series (Dujardin et al. 1980 a) we described general methods of selecting and genetically characterizing suppressor mutations that restore the respiratory capacity of mit- mitochondrial mutations. Two dominant nuclear (NAM1-1 and NAM2-1) and one mitochondrial (mim2-1) suppressors are more extensively studied in this paper. We have analysed the action spectrum of these suppressors on 433 mit- mutations located in various mitochondrial genes and found that they preferentially alleviate the effects of mutations located within intron open reading frames of the cob-box gene. We conclude that these suppressors permit the maturation of cytochrome b mRNA by restoring the synthesis of intron encoded protein(s) catalytically involved in splicing i.e. mRNA-maturase(s) (cf. Lazowska et al. 1980). NAM1-1 is allele specific and gene non-specific; it suppresses mutations located within different introns. NAM2-1 and mim2-1 are intron-specific: they suppress mutations all located in the same (box7) intron of the cob-box gene. Analyses of cytochrome absorption spectra and mitochondrial translation products of cells in which the suppressors are associated with various other mit- mutations show that the suppressors restore cytochrome b and/or cytochrome oxidase (cox I) synthesis, as expected from their growth phenotype. This suppression is, however, only partial: some new polypeptides characteristic of the mit- mutations can be still detected in the presence of suppressor. Interestingly enough when box7 specific suppressors NAM2-1 and mim2-1 are associated with a complete cob-box deletion (leading to a total deficiency of cytochrome b and oxidase) partial restoration of cox I synthesis is observed while cytochrome b is still totally absent. These results show that in strains carrying NAM2-1 or mim2-1 the presence of cytochrome b gene is no longer required for the expression of the oxi3 gene pointing out to the possibility of a mutational switch-on of silent genes, whether mitochondrial, mim2-1, or nuclear, NAM2-1. This switch-on would permit the synthesis of an active maturase acting as a substitute for the box7 maturase in order to splice the cytochrome b and oxidase mRNAs.

A mitochondrial locus is necessary for the synthesis of mitochondrial tRNA in the yeast Saccharomyces cerevisiae

We have used a cloned yeast mitochondrial tRNAUCNSer gene as a probe to detect RNA species that are transcripts from this gene in wild-type Saccharomyces cerevisiae and in petite deletion mutants. In RNA from wild-type cells, the tRNA is the most prominent transcript of the gene. In RNA from deletion mutants that retain this gene but have lost other regions of mtDNA, high molecular weight transcripts containing the tRNAUCNSer sequences accumulate but tRNAUCNSer is not made. tRNAUCNSer synthesis can be restored in these mutants when they are mated to other deletion mutants that retain a different portion of the mitochondrial genome. Protein synthesis is not necessary for the restoration, and the restoration is not due to a nuclear effect or to an effect of mating alone, because strains without mtDNA are not able to restore tRNA synthesis. These results definitively demonstrate the existence of a yeast mitochondrial locus that is necessary for tRNA synthesis and, because the restoration of tRNAUCNSer synthesis appears to result from intergenic complementation, not recombination, indicate that this locus acts in trans.

A low-molecular-weight RNA species in yeast mitochondria arising from a 3' end trimming of cytochrome b pre-mRNA

Immobilization of yeast mitochondrial RNA on nitrocellulose filters without prior alkali treatment revealed a low-MW RNA species (integral of 300 bases) which hybridizes specifically to the RNA coding strand of a DNA fragment BglII-HinfI at the 3' end of the COB-BOX gene. This RNA species (often a doublet) was found in several independent preparations of wild-type mtRNA and even in box- mutants blocked in the earliest steps of mRNA maturation (e.g. box 8-1). It may, therefore, result from an endonucleolytic cut similar to that which precedes the addition of a poly-A tail in other systems.