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

Pentatricopeptide Motifs in the N-Terminal Extension Domain of Yeast Mitochondrial RNA Polymerase Rpo41p Are Not Essential for Its Function

The core mitochondrial RNA polymerase is a single-subunit enzyme that in yeast Saccharomyces cerevisiae is encoded by the nuclear RPO41 gene. It is an evolutionary descendant of the bacteriophage RNA polymerases, but it includes an additional unconserved N-terminal extension (NTE) domain that is unique to the organellar enzymes. This domain mediates interactions between the polymerase and accessory regulatory factors, such as yeast Sls1p and Nam1p. Previous studies demonstrated that deletion of the entire NTE domain results only in a temperature-dependent respiratory deficiency. Several sequences related to the pentatricopeptide (PPR) motifs were identified in silico in Rpo41p, three of which are located in the NTE domain. PPR repeat proteins are a large family of organellar RNA-binding factors, mostly involved in posttranscriptional gene expression mechanisms. To study their function, we analyzed the phenotype of strains bearing Rpo41p variants where each of these motifs was deleted. We found that deletion of any of the three PPR motifs in the NTE domain does not affect respiratory growth at normal temperature, and it results in a moderate decrease in mtDNA stability. Steady-state levels of COX1 and COX2 mRNAs are also moderately affected. Only the deletion of the second motif results in a partial respiratory deficiency, manifested only at elevated temperature. Our results thus indicate that the PPR motifs do not play an essential role in the function of the NTE domain of the mitochondrial RNA polymerase.

A single mutation in the 15S rRNA gene confers non sense suppressor activity and interacts with mRF1 the release factor in yeast mitochondria

We have determined the nucleotide sequence of the mim3-1 mitochondrial ribosomal suppressor, acting on ochre mitochondrial mutations and one frameshift mutation in Saccharomyces cerevisiae. The 15s rRNA suppressor gene contains a G633 to C transversion. Yeast mitochondrial G633 corresponds to G517 of the E.coli 15S rRNA, which is occupied by an invariant G in all known small rRNA sequences. Interestingly, this mutation has occurred at the same position as the known MSU1 mitochondrial suppressor which changes G633 to A. The suppressor mutation lies in a highly conserved region of the rRNA, known in E.coli as the 530-loop, interacting with the S4, S5 and S12 ribosomal proteins. We also show an interesting interaction between the mitochondrial mim3-1 and the nuclear nam3-1 suppressors, both of which have the same action spectrum on mitochondrial mutations: nam3-1 abolishes the suppressor effect when present with mim3-1 in the same haploid cell. We discuss these results in the light of the nature of Nam3, identified by 1 as the yeast mitochondrial translation release factor. A hypothetical mechanism of suppression by "ribosome shifting" is also discussed in view of the nature of mutations suppressed and not suppressed.

Yeast model analysis of novel polymerase gamma variants found in patients with autosomal recessive mitochondrial disease

Replication of the mitochondrial genome depends on the single DNA polymerase (pol gamma). Mutations in the POLG gene, encoding the catalytic subunit of the human polymerase gamma, have been linked to a wide variety of mitochondrial disorders that show remarkable heterogeneity, with more than 200 sequence variants, often very rare, found in patients. The pathogenicity and dominance status of many such mutations remain, however, unclear. Remarkable structural and functional conservation of human POLG and its S. cerevisiae ortholog (Mip1p) led to the development of many successful yeast models, enabling to study the phenotype of putative pathogenic mutations. In a group of patients with suspicion of mitochondrial pathology, we identified five novel POLG sequence variants, four of which (p.Arg869Ter, p.Gln968Glu, p.Thr1053Argfs*6, and p.Val1106Ala), together with one previously known but uncharacterised variant (p.Arg309Cys), were amenable to modelling in yeast. Familial analysis indicated causal relationship of these variants with disease, consistent with autosomal recessive inheritance. To investigate the effect of these sequence changes on mtDNA replication, we obtained the corresponding yeast mip1 alleles (Arg265Cys, Arg672Ter, Arg770Glu, Thr809Ter, and Val863Ala, respectively) and tested their effect on mitochondrial genome stability and replication fidelity. For three of them (Arg265Cys, Arg672Ter, and Thr809Ter), we observed a strong, partially dominant phenotype of a complete loss of functional mtDNA, whereas the remaining two led to partial mtDNA depletion and significant increase in point mutation frequencies. These results show good correlation with the severity of symptoms observed in patients and allow to establish these variants as pathogenic mutations.

Mitochondrial and nuclear mitoribosomal suppressors that enable misreading of ochre codons in yeast mitochondria : I. Isolation, localization and allelism of suppressors

A systematic search for suppressors of mutations which cause a deficiency in the splicing of mitochondrial RNA has been undertaken. These splicing mutations were localized in the mRNA-maturase coding sequence of the second intron of the cob-boxgene, i.e. in the box3locus. A total of 953 revertants (mostly spontaneous in origin) were isolated and their genetic nature (nuclear vs. mitochondrial) and phenotype characterized.Most revertants were mitochondrially determined and displayed a wild-type phenotype. A mitochondrial suppressor unlinked with the box3 (-)target mutation was uncovered among the revertants displaying a pseudo-wild phenotype: out of 26 revertants analyzed, derived from 7 different box3(-) mutants only one such suppressor mutation mim3-1 was found. It was localized by rho(-) deletion mapping in the region between the oxi2 and oxi3 gene, within (or in the vicinity) the gene specifying the 15S ribosomal RNA.Nuclear suppressors were isolated from seven different box3 (-)mutants. All were recessive and had a pseudo-wild phenotype. Three such suppressors nam3-1, nam3-2 and nam3-3 were investigated more extensively. Tetrad analysis has shown that they are alleles of the same nuclear locus NAM3 and mitotic analysis has shown that they do not segregate mitotically.

Chloroplast gene suppression of defective ribulosebisphosphate carboxylase/oxygenase in Chlamydomonas reinhardii: evidence for stable heteroplasmic genes

The rcl-u-1-18-5B chloroplast mutation results in the absence of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) holoenzyme in the green alga Chlamydomonas reinhardii. The 18-5B mutant strain lacks photosynthesis and displays alight-sensitive, acetate-requiring phenotype. In the present investigations, revertants of 18-5B were recovered that regained photosynthetic competence. These revertants have decreased levels of Rubisco holoenzyme relative to wild type and display heteroplasmicity, segregating wild-type (revertant) and acetate-requiring phenotypes during vegetative growth or through meiosis. One of these revertants, R10-I, was studied further. The heteroplasmicity associated with photoautotrophically-grown R10-I was found to be stable through subcloning and heritable through several crosses. During growth in acetate medium in the dark, where photosynthesis provides no selective advantage, the wild-type phenotype was lost. Acetate-requiring segregants became homoplasmic but wild-type segregants did not. Organellar intergenic-suppression is discussed in light of the observed stable heteroplasmicity.

Mitochondrial and nuclear mitoribosomal suppressors that enable misreading of ochre codons in yeast mitochondria : II. Specificity and extent of suppressor action

We describe studies on the action spectra of the mitochondrial suppressor mim3-1 and the three alleles of nuclear suppressor nam3. Their specificity of action was tested on 516 mit (-) mutations located in different mitochondrial genes. The degree of suppression was quantified by the extent of cytochrome oxidase and cytochrome b synthesis. We show that the four suppressors are allele-specific gene-nonspecific informational suppressors. They would act by changing the structure of the small mitoribosomal subunit which would decrease fidelity of translation enabling misreading of some but not all ochre codons. The implications of the results on the role of intron encoded maturases are discussed.

Recombinational analysis of oxi2 mutants and preliminary analysis of their translation products in S. cerevisiae

Genetic and biochemical studies were performed with mutants allocated to the mitochondrial oxi2 gene.Recombinational analysis of 19 oxi2 mutants was performed using α and a mutant strains derived from the same genetic background. The frequencies of wild-type recombinants in oxi2 (-) × oxi2 (-) crosses varied from 0.002 to 17%. The map of oxi2 mutations constructed on the basis of these frequencies shows many internal inconsistencies. In the course of rho (-) deletion mapping five classes of oxi2 mutations were distinguished. The results of deletion analysis are in agreement with those of recombinational mapping.The analysis of mitochondrial translation products by SDS-polyacrylamide electrophoresis of 20 oxi2 mutants shows that 17 of them are connected with conspicuous changes of 22 kd polypeptide band corresponding to subunit III of cytochrome oxidase. At least four of them carried instead of subunit III clearly visible significantly shorter polypeptides (12.8 to 20.1 kd). These were, most likely, shorter fragments of subunit III resulting from chain termination mutations. Colinearity was observed between the lenght of new polypeptides and the positions of the respective mutations on the recombinational map. These data confirm hat oxi2 encodes subunit III of cytochrome oxidase and suggest that translation of the oxi2 gene is in the direction from V303 to V273.

Cell-specific differences in the requirements for translation quality control

Protein synthesis has an overall error rate of approximately 10(-4) for each mRNA codon translated. The fidelity of translation is mainly determined by two events: synthesis of cognate amino acid:tRNA pairs by aminoacyl-tRNA synthetases (aaRSs) and accurate selection of aminoacyl-tRNAs (aa-tRNAs) by the ribosome. To ensure faithful aa-tRNA synthesis, many aaRSs employ a proofreading ("editing") activity, such as phenylalanyl-tRNA synthetases (PheRS) that hydrolyze mischarged Tyr-tRNA(Phe). Eukaryotes maintain two distinct PheRS enzymes, a cytoplasmic (ctPheRS) and an organellar form. CtPheRS is similar to bacterial enzymes in that it consists of a heterotetramer in which the alpha-subunits contain the active site and the beta-subunits harbor the editing site. In contrast, mitochondrial PheRS (mtPheRS) is an alpha-subunit monomer that does not edit Tyr-tRNA(Phe), and a comparable transacting activity does not exist in organelles. Although mtPheRS does not edit, it is extremely specific as only one Tyr-tRNA(Phe) is synthesized for every approximately 7,300 Phe-tRNA(Phe), compatible with an error rate in translation of approximately 10(-4). When the error rate of mtPheRS was increased 17-fold, the corresponding strain could not grow on respiratory media and the mitochondrial genome was rapidly lost. In contrast, error-prone mtPheRS, editing-deficient ctPheRS, and their wild-type counterparts all supported cytoplasmic protein synthesis and cell growth. These striking differences reveal unexpectedly divergent requirements for quality control in different cell compartments and suggest that the limits of translational accuracy may be largely determined by cellular physiology.

DMR1 (CCM1/YGR150C) of Saccharomyces cerevisiae encodes an RNA-binding protein from the pentatricopeptide repeat family required for the maintenance of the mitochondrial 15S ribosomal RNA

Pentatricopeptide repeat (PPR) proteins form the largest known RNA-binding protein family and are found in all eukaryotes, being particularly abundant in higher plants. PPR proteins localize mostly in mitochondria and chloroplasts, where they modulate organellar genome expression on the post-transcriptional level. The Saccharomyces cerevisiae DMR1 (CCM1, YGR150C) encodes a PPR protein that localizes to mitochondria. Deletion of DMR1 results in a complete and irreversible loss of respiratory capacity and loss of wild-type mtDNA by conversion to rho(-)/rho(0) petites, regardless of the presence of introns in mtDNA. The phenotype of the dmr1Delta mitochondria is characterized by fragmentation of the small subunit mitochondrial rRNA (15S rRNA), that can be reversed by wild-type Dmr1p. Other mitochondrial transcripts, including the large subunit mitochondrial rRNA (21S rRNA), are not affected by the lack of Dmr1p. The purified Dmr1 protein specifically binds to different regions of 15S rRNA in vitro, consistent with the deletion phenotype. Dmr1p is therefore the first yeast PPR protein, which has an rRNA target and is probably involved in the biogenesis of mitochondrial ribosomes and translation.

Balance between transcription and RNA degradation is vital for Saccharomyces cerevisiae mitochondria: reduced transcription rescues the phenotype of deficient RNA degradation

The Saccharomyces cerevisiae SUV3 gene encodes the helicase component of the mitochondrial degradosome (mtEXO), the principal 3'-to-5' exoribonuclease of yeast mitochondria responsible for RNA turnover and surveillance. Inactivation of SUV3 (suv3Delta) causes multiple defects related to overaccumulation of aberrant transcripts and precursors, leading to a disruption of mitochondrial gene expression and loss of respiratory function. We isolated spontaneous suppressors that partially restore mitochondrial function in suv3Delta strains devoid of mitochondrial introns and found that they correspond to partial loss-of-function mutations in genes encoding the two subunits of the mitochondrial RNA polymerase (Rpo41p and Mtf1p) that severely reduce the transcription rate in mitochondria. These results show that reducing the transcription rate rescues defects in RNA turnover and demonstrates directly the vital importance of maintaining the balance between RNA synthesis and degradation.

Mitochondrial Mg(2+) homeostasis is critical for group II intron splicing in vivo

The product of the nuclear MRS2 gene, Mrs2p, is the only candidate splicing factor essential for all group II introns in mitochondria of the yeast Saccharomyces cerevisiae. It has been shown to be an integral protein of the inner mitochondrial membrane, structurally and functionally related to the bacterial CorA Mg(2+) transporter. Here we show that mutant alleles of the MRS2 gene as well as overexpression of this gene both increase intramitochondrial Mg(2+) concentrations and compensate for splicing defects of group II introns in mit(-) mutants M1301 and B-loop. Yet, covariation of Mg(2+) concentrations and splicing is similarly seen when some other genes affecting mitochondrial Mg(2+) concentrations are overexpressed in an mrs2Delta mutant, indicating that not the Mrs2 protein per se but certain Mg(2+) concentrations are essential for group II intron splicing. This critical role of Mg(2+) concentrations for splicing is further documented by our observation that pre-mRNAs, accumulated in mitochondria isolated from mutants, efficiently undergo splicing in organello when these mitochondria are incubated in the presence of 10 mM external Mg(2+) (mit(-) M1301) and an ionophore (mrs2Delta). This finding of an exceptional sensitivity of group II intron splicing toward Mg(2+) concentrations in vivo is unprecedented and raises the question of the role of Mg(2+) in other RNA-catalyzed reactions in vivo. It explains finally why protein factors modulating Mg(2+) homeostasis had been identified in genetic screens for bona fide RNA splicing factors.

A prokaryote and human tRNA synthetase provide an essential RNA splicing function in yeast mitochondria

Mitochondrial leucyl-tRNA synthetase (LeuRS) in the yeast Saccharomyces cerevisiae provides two essential functions. In addition to aminoacylation, LeuRS functions in RNA splicing. The details of how it came to act in splicing are not known. Here we show that Mycobacterium tuberculosis and human mitochondrial LeuRSs can substitute in splicing for the S. cerevisiae mitochondrial LeuRS. Mutations of yeast mitochondrial LeuRS that had previously been shown to abolish splicing activity also eliminate splicing by the M. tuberculosis enzyme. These results suggest the role of LeuRS in splicing in yeast mitochondria results from features of the enzyme that are broadly conserved in evolution. These features are not likely to be designed for splicing per se, but instead have been adopted in yeast for that purpose.

Suppressors of cis-acting splicing-deficient mutations that affect the ribozyme core of a group II intron

Many of the cis-dominant mutations that lead to respiratory deficiency by preventing maturation of specific yeast mitochondrial transcripts are found to affect the ribozyme core of group I and group II introns. We have searched for suppressors of mutations in the ribozyme-encoding sections of a group II intron, the first intron in the COX1 gene of Saccharomyces cerevisiae, which was independently subjected to in vitro site-directed mutagenesis. Three of the original mutants bore multiple mutations, which act synergistically, since for most individual mutations, suppressors could be obtained that ensured at least partial recovery of respiratory competence and splicing. Out of a total of ten suppressor mutations that were identified, three were second-site substitutions that restored postulated base-pairings in the ribozyme core. Remarkably, and as is observed for group I introns, at least half of the cis-dominant mutations in the first two group II introns of the COX1 gene affect sites that have been shown to participate in RNA tertiary interactions. We propose that this bias reflects cooperativity in the formation of ribozyme tertiary but not secondary structure, on the one hand, and the need for synergistic effects in order to generate a respiratory-deficient phenotype in the laboratory on the other. Finally, a novel in vivo splicing product of mutant cells is attributed to bimolecular splicing at high concentrations of defective transcripts.

A point mutation in the mitochondrial cytochrome b gene obviates the requirement for the nuclear encoded core protein 2 subunit in the cytochrome bc1 complex in Saccharomyces cerevisiae

A yeast mutant (cor2-45) in which approximately half of the C terminus of core protein 2 of the cytochrome bc1 complex is lacking due to a frameshift mutation that introduces a stop at codon 197 in the COR2 gene fails to assemble the cytochrome bc1 complex and does not grow on non-fermentable carbon sources that require respiration. The loss of respiration is more severe with this frameshift mutation than with the complete deletion of the COR2 gene, suggesting deleterious effects of the truncated core 2 protein. A search for extragenic suppressors of the nuclear cor2-45 mutation resulted (in addition to the expected nuclear suppressors) in the isolation of a suppressor mutation in the mitochondrial DNA that replaces serine 223 by proline in cytochrome b. Assembly of the cytochrome bc1 complex and the respiratory deficient phenotype of the cor2-45 mutant are restored by the proline for serine replacement in cytochrome b. Surprisingly, this amino acid replacement in cytochrome b corrects not only the phenotype resulting from the cor2-45 frameshift mutation, but it also obviates the need for core protein 2 in the cytochrome bc1 complex since it alleviates the respiratory deficiency resulting from the complete deletion of the COR2 gene. This is the first report of a homoplasmic missense point mutation of the mitochondrial DNA acting as a functional suppressor of a mutation located in a nuclear gene and the first demonstration that the supernumerary core protein 2 subunit is not essential for the electron transfer and energy transducing functions of the mitochondrial cytochrome bc1 complex.

In vitro mutagenesis of the mitochondrial leucyl tRNA synthetase of Saccharomyces cerevisiae shows that the suppressor activity of the mutant proteins is related to the splicing function of the wild-type protein

The NAM2 gene of Saccharomyces cerevisiae encodes the mitochondrial leucyl tRNA synthetase (mLRS), which is necessary for the excision of the fourth intron of the mitochondrial cytb gene (bI4) and the fourth intron of the mitochondrial coxI gene (aI4), as well as for mitochondrial protein synthesis. Some dominant mutant alleles of the gene are able to suppress mutations that inactivate the bI4 maturase, which is essential for the excision of the introns aI4 and bI4. Here we report mutagenesis studies which focus on the splicing and suppressor functions of the protein. Small deletions in the C-terminal region of the protein preferentially reduce the splicing, but not the synthetase activity; and all the C-terminal deletions tested abolish the suppressor activity. Mutations which increase the volume of the residue at position 240 in the wild-type mLRS without introducing a charge, lead to a suppressor activity. The mutant 238C, which is located in the suppressor region, has a reduced synthetase activity and no detectable splicing activity. These data show that the splicing and suppressor functions are linked and that the suppressor activity of the mutant alleles results from a modification of the wild-type splicing activity.

Subtelomeric duplications in Saccharomyces cerevisiae chromosomes III and XI: topology, arrangements, corrections of sequence and strain-specific polymorphism

We have determined the sequence of a 3.42 kb segment from the left arm of chromosome III (coordinates 5394-8815 of Oliver et al., 1992). Instead of four open reading frames (ORFs) listed previously, the verified sequence reveals the presence of only one ORF, renamed YCL070/73c, encoding a protein of 615 amino acids. The putative product of ORF YCL070/73c shows 98.5% identity and 99% similarity with the protein of the same length encoded by ORF YKR106w from the right arm of chromosome XI and displays a topology characteristic for the Major Facilitators Superfamily of membrane proteins. These corrections will be deposited in the EMBL data library under the Accession Number X59720. In strain S288C the subtelomeric sequence 4319-11 215 of chromosome III is 98.3% identical with the subtelomeric sequence of 658 204-665 061 from the right arm of chromosome XI. Using various subtelomeric probes from chromosome III (coordinates 2097-3646 of S288C) we have analysed eight different Saccharomyces cerevisiae strains and the closely related species S. douglasii: some S. cerevisiae strains have additional duplications and longer chromosomes XI; in all strains chromosome III contains the 1200-11 000 segment (strain FL100 is disomic) while S. douglasii does not show any hybridization in this region.

The sequence of 24.3 kb from chromosome X reveals five complete open reading frames, all of which correspond to new genes, and a tandem insertion of a Ty1 transposon

We have determined the complete nucleotide sequence of a 24.3 kb segment from chromosome X carried by the cosmid pEJ103. The sequence encodes five complete open reading frames (ORFs), none of which correspond to previously described genes; however, four of these ORFs display interesting similarities with sequences present in the databanks. The sequence also contains a tandem insertion of a Ty1 element. An investigation of the Ty1 polymorphism in other strains has revealed that the original insertion occurred within an ORF. Finally, the structure of the Ty1 repeat suggests a mechanism by which it may have been generated.

The S. cerevisiae nuclear gene SUV3 encoding a putative RNA helicase is necessary for the stability of mitochondrial transcripts containing multiple introns

The product of the nuclear gene SUV3 is implicated in a variety of post-transcriptional processes in yeast mitochondria. We have analysed the effect of SUV3 gene-disruption on the expression of intron-containing alleles of the mitochondrial cytb and cox1 genes. We have constructed several strains with mitochondrial genomes containing different combinations of cytb and cox1 introns, and associated these genomes with the disruption of SUV3. The resulting strains were tested for their respiratory competence and spectral cytochrome content. All the strains containing only two or three introns showed normal expression of cytb and cox1, whereas the strains containing more introns were unable to express the appropriate gene. The analysis of mitochondrial RNAs by Northern hybridisation showed that the loss of respiratory competence in the strains containing more introns is due to the decrease of mRNA level with no over-accumulation of high-molecular-weight precursors. However, the transcription of the genes was not affected. These results led us to the notion that SUV3 is required for the stability of intron-containing cytb and cox1 transcripts in a cumulative way, not dependent on any particular intron.

A multitude of suppressors of group II intron-splicing defects in yeast

Disruption of the nuclear MRS2 gene (mrs2-1 mutation) causes a strong pet- phenotype in strains with mitochondrial group II introns, and a leaky pet- phenotype in strains without group II introns. MRS3 and MRS4, the genes for two mitochondrial-solute carrier proteins, can suppress both phenotypes when present in high-copy-number plasmids. In order to search for further multicopy suppressors of the mrs2-1 mutant phenotype, an yeast genomic DNA library, MW90, was constructed in YEp351 from a strain deleted for the MRS2, MRS3 and MRS4 genes. Ten different Sau3A DNA fragments that act as multicopy suppressors of the mrs2-1 respiratory-deficient phenotype were isolated from this library. Some of the newly isolated genes suppress the pet- phenotypes of mrs2-1 cells in strains with and without mitochondrial group II introns. Other genes, however, are suppressors only for the mitochondrial intron-less strains. This supports the notion that the MRS2 gene product is bifunctional i.e., it is essential for the splicing of group II introns and is also involved in processes of mitochondrial biogenesis other than RNA splicing.

Identification of a new nuclear gene (CEM1) encoding a protein homologous to a beta-keto-acyl synthase which is essential for mitochondrial respiration in Saccharomyces cerevisiae

We have analysed a new gene, CEM1, from Saccharomyces cerevisiae. Inactivation of this gene leads to a respiratory-deficient phenotype. The deduced protein sequence shows strong similarities with beta-keto-acyl synthases or condensing enzymes. Typically, enzymes of this class are involved in the synthesis of fatty acids or similar molecules. An analysis of the mitochondrial lipids and fatty acids shows no major difference between the wild type and deleted strains, implying that the CEM1 gene product is not involved in the synthesis of the bulk fatty acids. Thus it is possible that the CEM1 protein is involved in the synthesis of a specialized molecule, probably related to a fatty acid, which is essential for mitochondrial respiration.

Genetic screening in Saccharomyces cerevisiae for large numbers of mitochondrial point mutations which affect structure and function of catalytic subunits of cytochrome-c oxidase

A new search for mitochondrial respiratory deficient mutants (Mit-) has been undertaken in order to accumulate a large number of point mutations in the coding portions of cytochrome-c-oxidase catalytic subunits and cytochrome b. Therefore, a mitochondrial DNA which retains the exons and lacks all the introns of the cytochrome oxidase subunit I and of the cytochrome-b split genes has been introduced into a strain carrying a nuclear recessive mutation affecting the adenine-nucleotide translocator, the op1 mutation, which is known to prevent the accumulation of large deletion petite mutants and this was used as the parental strain. After a moderate MnCl2 mutagenesis in order to limit multiple mutations, 105 Mit- mutants were isolated from 15,000 mutagenised clones in Saccharomyces cerevisiae. Mutations were mapped to the three catalytic subunits encoding genes (COX1, COX2 and COX3) of the cytochrome-c oxidase (70 mutations) and to the cytochrome-b gene (15 mutations). More than 50% of the mutants tested still exhibited mitochondrial translation products (subunits I, II and III), suggesting that they carry a missense mutation, rather than a nonsense mutation which would normally have led to a truncated protein. Mutations in the COX1 gene were allocated to four different subregions corresponding to exons 4 and 8 or to groups of exons, exons 1, 2, 3 or exons 5, 6, 7. Seven missense monosubstitution mutations and two frameshift mutations were also identified. The amino acid changes of the missense mutations were located in the vicinity of the CuB-heme alpha 3 binuclear centre ligands.

Genetic approaches to the study of mitochondrial biogenesis in yeast

In contrast to most other organisms, the yeast Saccharomyces cerevisiae can survive without functional mitochondria. This ability has been exploited in genetic approaches to the study of mitochondrial biogenesis. In the last two decades, mitochondrial genetics have made major contributions to the identification of genes on the mitochondrial genome, the mapping of these genes and the establishment of structure-function relationships in the products they encode. In parallel, more than 200 complementation groups, corresponding to as many nuclear genes necessary for mitochondrial function or biogenesis have been described. Many of the latter are required for post-transcriptional events in mitochondrial gene expression, including the processing of mitochondrial pre-RNAs, the translation of mitochondrial mRNAs, or the assembly of mitochondrial translation products into the membrane. The aim of this review is to describe the genetic approaches used to unravel the intricacies of mitochondrial biogenesis and to summarize recent insights gained from their application.

In vitro mutagenesis of the mitochondrial leucyl-tRNA synthetase of S. cerevisiae reveals residues critical for its in vivo activities

The mitochondrial leucyl-tRNA synthetase (mLRS) of Saccharomyces cerevisiae is involved in both mitochondrial protein synthesis and pre-mRNA splicing. We have created mutations in the regions HIGH, GWD and KMSKS, which are involved in ATP-, amino acid- and tRNA-binding respectively, and which have been conserved in the evolution of group I tRNA synthetases. The mutants GRD and NMSKS have no discernible phenotype. The mutants AWD and ARD act as null alleles and lead to the production of 100% cytoplasmic petites. The mutants HIGN, NIGH and KMSNS are unable to grow on glycerol even in the presence of an intronless mitochondrial genome and accumulate petites to a greater extent than the wild-type but less than 40%. Experiments with an imported bI4 maturase indicate that the lesion in these mutations primarily affects the synthetase and not the splicing functions.

The NAM8 gene in Saccharomyces cerevisiae encodes a protein with putative RNA binding motifs and acts as a suppressor of mitochondrial splicing deficiencies when overexpressed

We have characterized the nuclear gene NAM8 in Saccharomyces cerevisiae. It acts as a suppressor of mitochondrial splicing deficiencies when present on a multicopy plasmid. The suppressed mutations affect RNA folding and are located in both group I and group II introns. The gene is weakly transcribed in wild-type strains, its overexpression is a prerequisite for the suppressor action. Inactivation of the NAM8 gene does not affect cell viability, mitochondrial function or mitochondrial genome stability. The NAM8 gene encodes a protein of 523 amino acids which includes two conserved (RNP) motifs common to RNA-binding proteins from widely different organisms. This homology with RNA-binding proteins, together with the intronic location of the suppressed mitochondrial mutations, suggests that the NAM8 protein could be a non-essential component of the mitochondrial splicing machinery and, when present in increased amounts, it could convert a deficient intron RNA folding pattern into a productive one.

NAM7 nuclear gene encodes a novel member of a family of helicases with a Zn-ligand motif and is involved in mitochondrial functions in Saccharomyces cerevisiae

The yeast nuclear gene NAM7 was previously isolated within a genomic fragment of 7.7 kb (1 kb = 10(3) bases or base-pairs), having the ability to suppress mitochondrial intronic mutations defective in RNA splicing. We have identified and sequenced the region on the insert corresponding to the NAM7 gene. A long open reading frame has been revealed which could code for a protein of 971 amino acids. Comparison of the NAM7 putative protein with data libraries did not reveal any strong similarity with known proteins. However, the NAM7 protein contains several motifs typical for proteins interacting with nucleic acids: (1) five motifs diagnostic for a superfamily of helicases appear in the same order and with similar distances; (2) the N-terminal portion possesses potential Zn-ligand structures belonging to the C chi superfamily. Deletion of the chromosomal copy of NAM7 gene leads to a partial impairment in respiratory growth that is particularly striking at low temperature. Southern blot analysis of DNA extracted from a nam7 :: URA3 deleted strain revealed the presence of a second gene whose sequence is related to that of the NAM7 gene and which could participate in the same process.

NAM9 nuclear suppressor of mitochondrial ochre mutations in Saccharomyces cerevisiae codes for a protein homologous to S4 ribosomal proteins from chloroplasts, bacteria, and eucaryotes

We report the genetic characterization, molecular cloning, and sequencing of a novel nuclear suppressor, the NAM9 gene from Saccharomyces cerevisiae, which acts on mutations of mitochondrial DNA. The strain NAM9-1 was isolated as a respiration-competent revertant of a mitochondrial mit mutant which carries the V25 ochre mutation in the oxi1 gene. Genetic characterization of the NAM9-1 mutation has shown that it is a nuclear dominant omnipotent suppressor alleviating several mutations in all four mitochondrial genes tested and has suggested its informational, and probably ribosomal, character. The NAM9 gene was cloned by transformation of the recipient oxi1-V25 mutant to respiration competence by using a gene bank from the NAM9-1 rho o strain. Orthogonal-field alternation gel electrophoresis analysis and genetic mapping localized the NAM9 gene on the right arm of chromosome XIV. Sequence analysis of the NAM9 gene showed that it encodes a basic protein of 485 amino acids with a presequence that could target the protein to the mitochondrial matrix. The N-terminal sequence of 200 amino acids of the deduced NAM9 product strongly resembles the S4 ribosomal proteins from chloroplasts and bacteria. Significant although less extensive similarity was found with ribosomal cytoplasmic proteins from lower eucaryotes, including S. cerevisiae. Chromosomal inactivation of the NAM9+ gene is not lethal to the cell but leads to respiration deficiency and loss of mitochondrial DNA integrity. We conclude that the NAM9 gene product is a mitochondrial ribosomal counterpart of S4 ribosomal proteins found in other systems and that the suppressor acts through decreasing the fidelity of translation.

NAM9 nuclear suppressor of mitochondrial ochre mutations in Saccharomyces cerevisiae codes for a protein homologous to S4 ribosomal proteins from chloroplasts, bacteria, and eucaryotes

We report the genetic characterization, molecular cloning, and sequencing of a novel nuclear suppressor, the NAM9 gene from Saccharomyces cerevisiae, which acts on mutations of mitochondrial DNA. The strain NAM9-1 was isolated as a respiration-competent revertant of a mitochondrial mit mutant which carries the V25 ochre mutation in the oxi1 gene. Genetic characterization of the NAM9-1 mutation has shown that it is a nuclear dominant omnipotent suppressor alleviating several mutations in all four mitochondrial genes tested and has suggested its informational, and probably ribosomal, character. The NAM9 gene was cloned by transformation of the recipient oxi1-V25 mutant to respiration competence by using a gene bank from the NAM9-1 rho o strain. Orthogonal-field alternation gel electrophoresis analysis and genetic mapping localized the NAM9 gene on the right arm of chromosome XIV. Sequence analysis of the NAM9 gene showed that it encodes a basic protein of 485 amino acids with a presequence that could target the protein to the mitochondrial matrix. The N-terminal sequence of 200 amino acids of the deduced NAM9 product strongly resembles the S4 ribosomal proteins from chloroplasts and bacteria. Significant although less extensive similarity was found with ribosomal cytoplasmic proteins from lower eucaryotes, including S. cerevisiae. Chromosomal inactivation of the NAM9+ gene is not lethal to the cell but leads to respiration deficiency and loss of mitochondrial DNA integrity. We conclude that the NAM9 gene product is a mitochondrial ribosomal counterpart of S4 ribosomal proteins found in other systems and that the suppressor acts through decreasing the fidelity of translation.

PET genes of Saccharomyces cerevisiae

We describe a collection of nuclear respiratory-defective mutants (pet mutants) of Saccharomyces cerevisiae consisting of 215 complementation groups. This set of mutants probably represents a substantial fraction of the total genetic information of the nucleus required for the maintenance of functional mitochondria in S. cerevisiae. The biochemical lesions of mutants in approximately 50 complementation groups have been related to single enzymes or biosynthetic pathways, and the corresponding wild-type genes have been cloned and their structures have been determined. The genes defined by an additional 20 complementation groups were identified by allelism tests with mutants characterized in other laboratories. Mutants representative of the remaining complementation groups have been assigned to one of the following five phenotypic classes: (i) deficiency in cytochrome oxidase, (ii) deficiency in coenzyme QH2-cytochrome c reductase, (iii) deficiency in mitochondrial ATPase, (iv) absence of mitochondrial protein synthesis, and (v) normal composition of respiratory-chain complexes and of oligomycin-sensitive ATPase. In addition to the genes identified through biochemical and genetic analyses of the pet mutants, we have cataloged PET genes not matched to complementation groups in the mutant collection and other genes whose products function in the mitochondria but are not necessary for respiration. Together, this information provides an up-to-date list of the known genes coding for mitochondrial constituents and for proteins whose expression is vital for the respiratory competence of S. cerevisiae.

Two group I mitochondrial introns in the cob-box and coxI genes require the same MRS1/PET157 nuclear gene product for splicing

We have studied the role of the product of the nuclear gene PET157 in mitochondrial pre-mRNA splicing. Cytoduction experiments show that a mitochondrial genome deleted for the three introns bI3, aI5 and aI6 is able to suppress the pet157-1 mutation: the strain recovers respiratory competency indicating that the product of the PET157 gene is only required for mitochondrial pre-mRNA splicing. Characterization of the high molecular weight pre-mRNAs which accumulate in the pet157 mutant demonstrate that the product of the PET157 gene is required for the excision of two group I introns bI3 and aI6 (corresponding to aI5 beta) located in the cob-box and coxI genes respectively. Furthermore, the pet157 mutant strain accumulates the bI3 maturase in the form of a polypeptide of 50K (p50) previously observed in mitochondrial mutants defective in the excision of bI3. We have shown by restriction analysis and allelism tests that the pet157-1 mutation is allelic to the nuclear mrs1 mutation, previously described as specifically blocking the excision of bI3. Finally, revertants obtained by the deletion of bI3 or aI6 from the mitochondrial DNA were isolated from the MRS1 disrupted allele, confirming the involvement of the product of the MRS1/PET157 gene in the excision of the two introns bI3 and aI6.

An essential yeast protein, encoded by duplicated genes TIF1 and TIF2 and homologous to the mammalian translation initiation factor eIF-4A, can suppress a mitochondrial missense mutation

We describe the isolation and characterization of two previously undescribed genes, TIF1 and TIF2, from Saccharomyces cerevisiae. The protein-encoding sequences of the two genes are highly conserved, resulting in two completely identical proteins, whereas the flanking regions show no obvious homology. The two yeast proteins are highly similar to the translation initiation factor eIF-4A from mouse. Elevated gene dosage of TIF1 or TIF2 results in the suppression of a missense mutation in the mitochondrial oxi2 gene, which codes for subunit III of cytochrome-c oxidase, although the sequence of the Tif protein indicates its cytoplasmic localization. Inactivation of either gene by gene disruption has no effect on cell viability or on mitochondrial functions. However, simultaneous inactivation of both genes is lethal to the cell.

Site-specific DNA endonuclease and RNA maturase activities of two homologous intron-encoded proteins from yeast mitochondria

Two introns of the mitochondrial genome 777-3A of S. cerevisiae, bl4 in cob and al4 in coxl genes, contain ORFs that can be translated into two homologous proteins. We changed the UGA, AUA, and CUN codons of these ORFs to the universal genetic code, in order to study the functions of their translated products in E. coli and in yeast, by retargeting the nuclear encoded protein into mitochondria. The p27bl4 protein has been shown to be required for the splicing of both introns bl4 and al4. The homologous p28al4 protein is highly toxic to E. coli. It can specifically cleave double-stranded DNA at a sequence representing the junction of the two fused flanking exons. We present evidence that this system is a good model for studying the role of mitochondrial intron-encoded proteins in the rearrangement of genetic information at both the RNA (RNA splicing-bl4 maturase) and DNA levels (intron transposition-al4 transposase).

Novel class of nuclear genes involved in both mRNA splicing and protein synthesis in Saccharomyces cerevisiae mitochondria

We have cloned three distinct nuclear genes, NAM1, NAM7, and NAM8, which alleviate mitochondrial intron mutations of the cytochrome b and COXI (subunit I of cytochrome oxidase) genes when present on multicopy plasmids. These nuclear genes show no sequence homology to each other and are localized on different chromosomes: NAM1 on chromosome IV, NAM7 on chromosome XIII and NAM8 on chromosome VIII. Sequence analysis of the NAM1 gene shows that it encodes a protein of 440 amino acids with a typical presequence that would target the protein to the mitochondrial matrix. Inactivation of the NAM1 gene by gene transplacement leads to a dramatic reduction of the overall synthesis of mitochondrial protein, and a complete absence of the COXI protein which is the result of a specific block in COXI pre-mRNA splicing. The possible mechanisms by which the NAM1 gene product may function are discussed.

Molecular genetics of group I introns: RNA structures and protein factors required for splicing--a review

In vivo and in vitro genetic techniques have been widely used to investigate the structure-function relationships and requirements for splicing of group-I introns. Analyses of group-I introns from extremely diverse genetic systems, including fungal mitochondria, protozoan nuclei, and bacteriophages, have yielded results which are complementary and highly consistent. In vivo genetic studies of fungal mitochondrial systems have served to identify cis-acting sequences within mitochondrial introns, and trans-acting protein products of mitochondrial and nuclear genes which are important for splicing, and to show that some mitochondrial introns are mobile genetic elements. In vitro genetic studies of the self-splicing intron within the Tetrahymena thermophila nuclear large ribosomal RNA precursor (Tetrahymena LSU intron) have been used to examine essential and nonessential RNA sequences and structures in RNA-catalyzed splicing. In vivo and in vitro genetic analysis of the intron within the bacteriophage T4 td gene has permitted the detailed examination of mutant phenotypes by analyzing splicing in vivo and self-splicing in vitro. The genetic studies combined with phylogenetic analysis of intron structure based on comparative nucleotide sequence data [Cech 73 (1988) 259-271] and with biochemical data obtained from in vitro splicing experiments have resulted in significant advances in understanding the biology and chemistry of group-I introns.

Divergence of the mitochondrial leucyl tRNA synthetase genes in two closely related yeasts Saccharomyces cerevisiae and Saccharomyces douglasii: a paradigm of incipient evolution

We studied the NAM2 genes of Saccharomyces douglasii and Saccharomyces cerevisiae, and showed that they are interchangeable for all the known functions of these genes, both mitochondrial protein synthesis and mitochondrial mRNA splicing. This confirms the prediction that the S. douglasii NAM2D gene encodes the mitochondrial leucyl tRNA synthetase (EC 6.1.1.4.). The observation that these enzymes are interchangeable for their mRNA splicing functions, even though there are significant differences in the intron/exon structure of their mitochondrial genome, suggests that they may have a general role in yeast mitochondrial RNA splicing. A short open reading frame (ORF) precedes the synthetase-encoding ORF, and we showed that at least in S. cerevisiae this is not essential for the expression of the gene; however, it may be involved in a more subtle type of regulation. Sequence comparisons of S. douglasii and S. cerevisiae revealed a particularly interesting situation from the evolutionary point of view. It appears that the two yeasts have diverged relatively recently: there is remarkable nucleotide sequence conservation, with no deletions or insertions, but numerous (albeit non-saturating) silent substitutions resulting from transitions. This applies not only to the NAM2 coding regions, but also to two other ORFs flanking the NAM2 ORF. The regions between the ORFs (believed to be intergenic regions) are much less conserved, with several deletions and insertions. Thus S. douglasii and S. cerevisiae provide an ideal system for the study of molecular evolution, being two yeasts "caught in the act" of speciation.

Nuclear omnipotent suppressors of premature termination codons in mitochondrial genes affect the 37S mitoribosomal subunit

nam3 and R705, yeast nuclear omnipotent suppressors of mitochondrial mit- mutations, reverse the superimposed spectrum of trans-recessive splicing defects by affecting the protein composition of the small mitoribosomal subunit. Analysis of the suppressor's interaction suggests that suppression results from mutations in the mitoribosomal polypeptides. These data indicate an obligatory connection between mitoribosome function and splicing of introns bI2, bI4 and aI1 in yeast mitochondria.

Three nuclear genes suppress a yeast mitochondrial splice defect when present in high copy number

A gene bank of a yeast wild type DNA in the high copy number vector YEp13 was screened for recombinant plasmids which suppress the mitochondrial RNA splice defect exerted by mutant M1301, a -1 bp deletion in the first intron of the mitochondrial COB gene (bI1). A total of 17 recombinant plasmids with similar suppressor activity were found. Restriction mapping and cross-hybridization of the inserts revealed that these 17 plasmids contain three different inserts, all lacking any extended sequence homology. Each of the inserts, when present in high copy number, has a similar suppressor activity: high in the presence of mutation M1301 in bI1, a group II intron, and low but significant with the presence of few mutants in bI2 and bI3 of the COB gene, both of which are group I introns.

Cloning of a nuclear gene MRS1 involved in the excision of a single group I intron (bI3) from the mitochondrial COB transcript in S. cerevisiae

The respiratory deficient yeast nuclear mutant MK3 is defective in the synthesis of the mature transcripts of the mitochondrial COB and OX13 genes, which code for apocytochrome b and subunit I of cytochrome c oxidase, resp. Introns 3 and 4 of the COB transcript (bI3 and bI4) and intron 4 (aI4) of the OXI3 transcript can not be excised (Pillar et al. 1983a, b). When combined with mitochondrial genomes lacking introns bI1, bI2 and bI3, or lacking intron bI3 alone the mutant is respiratory competent. Thus, the non-excision of bI4 and aI4 turns out to be an indirect effect of the mutation. From a wild type yeast genebank a plasmid has been isolated with a 3.3 kb DNA insert, which complements the mutant. Subcloning experiments assigned the functional gene to a 1.6 kb HaeIII-Sau3A fragment. Hybridization experiments showed, that it is (i) a single copy gene, (ii) also present in strain D273-10B, containing the "short form" mitochondrial genome (lacking the COB introns bI1-bI3), and (iii) located on chromosome IX. The nuclear gene defective in mutant MK3, was named MRS1 (Mitochondrial RNA Splicing). The involvement of this nuclear gene in the excision of a single group I mitochondrial intron (bI3) of the COB transcript is discussed.

Nuclear-mitochondrial interactions in cytoplasmic male-sterile sorghum

Variation in mitochondrial genome organization and expression between male fertile and sterile nuclear-cytoplasmic combinations of sorghum has been examined. Cytoplasmic genotypes were classified into eleven groups on the basis of restriction endonuclease digestion of mitochondrial DNA (mtDNA) and five groups on the basis of mitochondrial translation products. These cytoplasms were further characterized by hybridization of specific gene probes to Southern blots of EcoRI digested mtDNA, and identification of the fragment location of four mitochondrial genes. Variation was observed in the genomic location and copy number of the F1 ATPase α-subunit gene, as well as the genomic location and gene product of the cytochrome c oxidase subunit I gene. The effect of nuclear genotype on mitochondrial genome organization, expression and the presence of two linear plasmid-like mtDNA molecules was examined. Our results indicate that nuclear-mitochondrial interactions are required for regulation of mitochondrial gene expression. When a cytoplasm is transferred from its natural to a foreign nuclear background some changes in the products of in organello mitochondrial protein synthesis occur. In a number of cytoplasmic genotypes these changes correlate with the expression of cytoplasmic male sterile phenotype, suggesting a possible molecular basis for this mutation.

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.

The yeast nuclear gene NAM2 is essential for mitochondrial DNA integrity and can cure a mitochondrial RNA-maturase deficiency

Dominant mutations in the yeast nuclear gene NAM2 cure the RNA splicing deficiency resulting from the inactivation of the bI4 maturase encoded by the fourth intron of the mitochondrial cytochrome b gene. This maturase is required to splice the fourth intron of this gene and to splice the fourth intron of the mitochondrial gene oxi3 encoding cytochrome oxidase subunit I. We have cloned the nuclear gene NAM2, which codes for two overlapping RNAs, 3.2 kb and 3.0 kb long, which are transcribed in the same direction but differ at their 5' ends. NAM2 compensating mutations probably result from point mutations in the structural gene. Integration of the cloned gene occurs at its homologous locus on the right arm of chromosome XII. Inactivation of the NAM2 gene either by transplacement with a deleted copy of the gene, or by disruption, is not lethal to the cell, but leads to the destruction of the mitochondrial genome with the production of 100% cytoplasmic petites.

Functional nuclear suppressor of mitochondrial oxi2 mutations in yeast

A semidominant nuclear suppressor, called nam6, of oxi2-V276 mitochondrial mutation has been isolated and characterized. The nuclear character of nam6 was proved by its retention in rho degree strains, lack of mitotic segregation in diploids and meiotic 2:2 segregation in tetrads. The specificity of nam6 was tested on 315 mit- mutations of four mitochondrial genes (oxi1, oxi2, oxi3, and cob-box). It suppresses clearly only three mutations in the oxi2 gene, restoring partially or completely cytochrome aa3 formation. The results suggest a functional character of the suppression.

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.

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.

Cytochrome b of cob revertants in yeast. 1. Isolation and characterization of revertants derived from cob exon mutants of Saccharomyces cerevisiae

About 300 revertants were derived from 44 cob- mutants, mapping in the structure coding regions (exon 1, 3, 4, 5, or 6) of the mitochondrial apocytochrome b gene in Saccharomyces cerevisiae, strain 777-3A. Most of the revertants could not be distinguished from the wild-type by means of physiological properties. Twenty-two revertants different in phenotype are described here in more detail. The suppressor mutations (supa) that compensate the primary cob- mutations (i.e., restore growth on glycerol) are mitochondrially inherited. They were localized in the same cob exon regions as the respective primary mutations, except for one revertant with a primary mutation in exon 6 and a suppressor, 4.2 map units distant, which may be located either in intron 5 or downstream in exon 6. Of 21 suppressors 17 are closely coupled to the primary mutation with recombination frequencies of less than or equal to 0.1%-0.3%. An estimate predicts that in more than 80% of these revertants only one amino acid is altered at that point of the polypeptide corresponding to the cob- site in the gene. The most interesting revertant phenotypes are: reduced growth rate on glycerol. The respective cob-/supa mutations are scattered over the whole cob region and cannot be correlated exclusively with special gene regions. decreased cytochrome b content. The most extreme reductions (28% and 30% of wild-type level) were observed to be due to mutations located in the 5' proximal part of exon 1. The highest percentage of revertants with decreased cytochrome b content was predominantly found mapping in exon 3.(ABSTRACT TRUNCATED AT 250 WORDS)

Steps in processing of the mitochondrial cytochrome oxidase subunit I pre-mRNA affected by a nuclear mutation in yeast

In Saccharomyces cerevisiae, the mitochondrial gene encoding the subunit I of cytochrome c oxidase (oxi-3 gene) is interrupted by intervening sequences. In this report, a nuclear mutation [referred to as mss51 in Faye, G. & Simon, M. (1983) Cell 32, 77-87] that specifically affects the processing of oxi-3 pre-mRNA was further characterized. DNA probes covering each oxi-3 exon-intron boundary were individually hybridized to wild-type and mutant mitochondrial RNA. By a technique relying on the S1 nuclease resistance or sensitivity of the RNA X DNA hybrids thereof, we have shown which site needs the MSS51 gene product to be cleaved. The mutation in the MSS51 gene gave rise to a complex pattern of splicing: the third intron was excised efficiently but the first two introns remained bracketed by their flanking exons. Further, the fourth and fifth introns were only partially split from their common exon and remained fused to their upstream and downstream flanking exon, respectively. Several plausible roles for the MSS51 gene product are discussed.