Suppression of a +1 T mutation by a nearby substitution in the mitochondrial cox1 gene of Chlamydomonas reinhardtii : a new type of frameshift suppression in an organelle genome

In Chlamydomonas reinhardtii, mutants defective in the cytochrome pathway of respiration lack the capacity to grow under heterotrophic conditions (in darkness on acetate). In the dark^? strain dum18, a +1?T addition in a run of four Ts, located at codon 145 of the mitochondrial cox1 gene encoding subunit I of cytochrome c oxidase, is responsible for the mutant phenotype. A leaky revertant (su11) that grows heterotrophically at a lower rate than wild-type cells was isolated from dum18. Its respiration sensitivity to cyanide was low and its cytochrome c oxidase activity was only 4% of that of the wild-type enzyme. Meiotic progeny obtained from crosses between revertant and wild-type cells inherited the phenotype of the mt ^? parent, showing that the suppressor mutation, like dum18 itself, is located in the mitochondrial genome. In order to map the su11 mutation relative to dum18, a recombinational analysis was performed on the diploid progeny. It demonstrated that su11 was very closely linked to the dum18 mutation – less than 20–30?bp away. The cox1 gene of the su11 revertant was then sequenced. In addition to the +1?T frameshift mutation still present at codon 145, an A?→?C substitution was found at codon 146, leading to the replacement of a glutamic acid by an alanine in the polypeptide chain. No other mutations were detected in the cox1 coding sequence. As the new GCG codon (Ala) created at position 146 is very seldom used in the mitochondrial genome of C. reinhardtii, we suggest that the partial frameshift suppression by the nearby substitution is due to an occasional abnormal translocation of the ribosome (+1 base shift) facilitated both by the run of Ts and the low level of weak interaction of alanyl-tRNA.     

Suppression of a +1?T mutation by a nearby substitution in the mitochondrial cox1 gene of Chlamydomonas reinhardtii : a new type of frameshift suppression in an organelle genome

In Chlamydomonas reinhardtii, mutants defective in the cytochrome pathway of respiration lack the capacity to grow under heterotrophic conditions (in darkness on acetate). In the dark⁻ strain dum18, a +1 T addition in a run of four Ts, located at codon 145 of the mitochondrial cox1 gene encoding subunit I of cytochrome c oxidase, is responsible for the mutant phenotype. A leaky revertant (su11) that grows heterotrophically at a lower rate than wild-type cells was isolated from dum18. Its respiration sensitivity to cyanide was low and its cytochrome c oxidase activity was only 4% of that of the wild-type enzyme. Meiotic progeny obtained from crosses between revertant and wild-type cells inherited the phenotype of the mt ⁻ parent, showing that the suppressor mutation, like dum18 itself, is located in the mitochondrial genome. In order to map the su11 mutation relative to dum18, a recombinational analysis was performed on the diploid progeny. It demonstrated that su11 was very closely linked to the dum18 mutation – less than 20–30 bp away. The cox1 gene of the su11 revertant was then sequenced. In addition to the +1 T frameshift mutation still present at codon 145, an A → C substitution was found at codon 146, leading to the replacement of a glutamic acid by an alanine in the polypeptide chain. No other mutations were detected in the cox1 coding sequence. As the new GCG codon (Ala) created at position 146 is very seldom used in the mitochondrial genome of C. reinhardtii, we suggest that the partial frameshift suppression by the nearby substitution is due to an occasional abnormal translocation of the ribosome (+1 base shift) facilitated both by the run of Ts and the low level of weak interaction of alanyl-tRNA. Received: 27 January 1998 / Accepted: 5 May 1998     

Alteration of dark respiration and reduction of phototrophic growth in a mitochondrial DNA deletion mutant of Chlamydomonas lacking cob, nd4, and the 3' end of nd5.

We describe here a new type of mitochondrial mutation (dum24; for dark uniparental minus inheritance) of the unicellular photosynthetic alga Chlamydomonas reinhardtii. The mutant fails to grow under heterotrophic conditions and displays reduced growth under both photoautotrophic and mixotrophic conditions. In reciprocal crosses between mutant and wild-type cells, the meiotic progeny only inherit the phenotype of the mating-type minus parent, indicating that the dum24 mutation exclusively affects the mitochondrial genome. Digestion with various restriction enzymes followed by DNA gel blot hybridizations with specific probes demonstrated that dum24 cells contain four types of altered mitochondrial genomes: deleted monomers lacking cob, nd4, and the 3' end of the nd5 gene; deleted monomers deprived of cob, nd4, nd5, and the 5' end of the cox1 coding sequence; and two types of dimers produced by end-to-end fusions between monomers similarly or differently deleted. Due to these mitochondrial DNA alterations, complex I activity, the cytochrome pathway of respiration, and presumably, the three phosphorylation sites associated with these enzyme activities are lacking in the mutant. The low respiratory rate of the dum24 cells results from the activities of rotenone-resistant NADH dehydrogenase, complex II, and alternative oxidase, with none of these enzymes being coupled to ATP production. To our knowledge, this type of mitochondrial mutation has never been described for photosynthetic organisms or more generally for obligate aerobes.     

The pho1 mutation. A frameshift, and its compensation, producing altered forms of physiologically efficient ATPase in yeast mitochondria

The pho1 mutation belongs to the OL12 gene on mitochondrial DNA of Saccharomyces cerevisiae, which codes for a membrane factor subunit of the mitochondrial ATPase (apparent molecular mass 20 kDa). We analysed the ATPase complex from the pho1 mutant and from three revertants, after immunoprecipitation from mitochondrial extracts, by dodecyl sulphate/acrylamide gel electrophoresis. In two revertants the OL12 gene product appeared as an abundant slower migrating peptide, while in the pho mutant, two bands appeared in very low amounts. For the third revertant, a strong band appeared at the normal level. Sequencing of the OL12 gene from these strains gave the following results: the pho1 mutation is a frameshift, arising by insertion of an extra thymidine into a group of three. Two of the revertants contain the same group of four thymidines, but genetic compensation of the frameshift occurs 24 base pairs downstream by the loss of four bases, implying a deficit of one codon. The third revertant has recovered the normal three-thymidine sequence. There is excellent correlation between the modified sequences and electrophoretic migration of the peptide product. Owing to the leakiness of the pho1 phenotype (reduced but not nil growth rate on oxidizable carbon sources, 5-10% highly oligomycin-sensitive ATPase complex, low amounts of OL12 gene product peptides), some translational correction of the frameshift is bound to occur. Based on these results, the compatibility of abnormal ATPase architecture with modified energetic efficiency is discussed.     

Suppression of a defect in the 5'' untranslated leader of mitochondrial COX3 mRNA by a mutation affecting an mRNA-specific translational activator protein.

Translation of the Saccharomyces cerevisiae mitochondrial COX3 mRNA, encoding subunit III of cytochrome c oxidase, specifically requires the action of the nuclear gene products PET54, PET122, and PET494 at a site encoded in the 612-base 5' untranslated leader. To identify more precisely the site of action of the translational activators, we constructed two large deletions of the COX3 mRNA 5' untranslated leader. Both deletions blocked translation without affecting mRNA stability. However, one of the large deletions was able to revert to partial function by a small secondary deletion within the remaining 5' leader sequences. Translation of the resulting mutant (cox3-15) mRNA was still dependent on the nuclear-encoded specific activators but was cold sensitive. We selected revertants of this mitochondrial mutant at low temperature to identify genes encoding proteins that might interact with the COX3 mRNA 5' leader. One such revertant carried a missense mutation in the PET122 gene that was a strong and dominant suppressor of the cold-sensitive defect in the mRNA, indicating that the PET122 protein interacts functionally (possibly directly) with the COX3 mRNA 5' leader. The cox3-15 mutation was not suppressed by overproduction of the wild-type PET122 protein but was very weakly suppressed by overproduction of PET494 and slightly better suppressed by co-overproduction of PET494 and PET122.     

Suppression of a nuclear frameshift mutation by a mitochondrial tRNA in the yeast Kluyveromyces lactis

A fragment of mitochondrial DNA containing the Kluyveromyces lactis gene for valine-tRNA (tRNAVAL) was isolated as a multicopy suppressor of a respiratory-deficient mutant of this yeast. The mutant produced a truncated Cox14p because of a +1 frameshift mutation in COX14, a nuclear gene encoding a protein imported into mitochondria which is necessary for respiration (Fiori et al. 2000 Yeast 16: 307-314). We report here that the mitochondrial tRNAVAL gene, when transformed into K. lactis cells, is transcribed outside mitochondria and suppresses the frameshift mutation in COX14 restoring the correct reading frame during translation of its mRNA. In fact, using histidine tagging, the existence of a suppressed Cox14p of normal length was demonstrated in mutants expressing the mt-tRNAVAL from the nucleus. Suppression could occur through a non-canonical four base pairing between the tRNAVAL and the mutated mRNA or through slippage of ribosomes during translation. This is a new case of informational suppression in that the suppression of a chromosomal mutation is not caused by a second mutation but to a mislocalization/expression of a mt-tRNA.     

Intragenic suppression of a deletion mutation of the nonstructural gene of an influenza A virus.

The influenza A/Alaska/77 (H3N2) virus mutant 143-1 is temperature sensitive (ts) due to a spontaneous in-frame 36-nucleotide deletion in the nonstructural (NS) gene segment, which leads to a 12-amino-acid deletion in the NS1 protein. In addition, it has a small-plaque phenotype on MDCK cell monolayers. However, phenotypically revertant (i.e., ts+) viruses were isolated readily following replication of the 143-1 virus both in vitro and in vivo. In order to determine the genetic mechanism by which escape from the ts phenotype occurred, we performed segregational analysis and found that an intrasegmental suppressor mutation caused the loss of the ts phenotype. Nucleotide sequence analysis revealed the presence of an intragenic mutation in each of the ts+ phenotypic revertant viruses, involving a substitution of valine for alanine at amino acid 23 of the NS1 protein. This mutation resulted in acquisition of the ts+ phenotype and also in the large-plaque phenotype on MDCK cells, characteristic of the wild-type A/Alaska/77 parent virus. This amino acid substitution is predicted to generate an area of alpha helix in the secondary structure of the amino-terminal portion of the NS1 protein of the revertant viruses which may compensate for loss of an alpha-helical region due to the deletion of amino acids 66 to 77 in the NS1 protein of the 143-1 virus.     

Mutations in MTO2 related to tRNA modification impair mitochondrial gene expression and protein synthesis in the presence of a paromomycin resistance mutation in mitochondrial 15 S rRNA

Nuclear gene(s) have been shown to modulate the phenotypic expression of mitochondrial DNA mutations. We report here the identification and characterization of the yeast nuclear gene MTO2 encoding an evolutionarily conserved protein involved in mitochondrial tRNA modification. Interestingly, mto2 null mutants expressed a respiratory-deficient phenotype when coexisting with the C1409G mutation of mitochondrial 15 S rRNA at the very conservative site for human deafness-associated 12 S rRNA A1491G and C1409T mutations. Furthermore, the overall rate of mitochondrial translation was markedly reduced in a yeast mto2 strain in the wild type mitochondrial background, whereas mitochondrial protein synthesis was almost abolished in a yeast mto2 strain carrying the C1409G allele. The other interesting feature of mto2 mutants is the defective expression of mitochondrial genes, especially CYTB and COX1, but only when coexisting with the C1409G allele. These data strongly indicate that a product of MTO2 functionally interacts with the decoding region of 15 S rRNA, particularly at the site of the C1409G or A1491G mutation. In addition, we showed that yeast and human Mto2p localize in mitochondria. The isolated human MTO2 cDNA can partially restore the respiratory-deficient phenotype of yeast mto2 cells carrying the C1409G mutation. These functional conservations imply that human MTO2 may act as a modifier gene, modulating the phenotypic expression of the deafness-associated A1491G or C1409T mutation in mitochondrial 12 S rRNA.     

Assembly of the Mitochondrial Membrane System: Nuclear Suppression of a Cytochrome b Mutation in Yeast Mitochondrial DNA

In a previous study, a mitochondrial mutant expressing a specific enzymatic deficiency in co-enzyme QH₂-cytochrome c reductase was described (Tzagoloff, Foury and Akai 1976). Analysis of the mitochondrially translated proteins revealed the absence in the mutant of the mitochondrial product corresponding to cytochrome b and the presence of a new low molecular weight product. The premature chain-termination mutant was used to obtain suppressor mutants with wild-type properties. One such revertant strain was analyzed genetically and biochemically. The revertant was determined to have a second mutation in a nuclear gene that is capable of partially suppressing the original mitochondrial cytochrome b mutation. Genetic data indicate that the nuclear mutation is recessive and is probably in a gene coding for a protein involved in the mitochondrial translation machinery.     

Suppression of a double missense mutation by a mutant tRNA(Phe) in Escherichia coli.

We report here the isolation of a mutant tRNAPhe that suppresses a double missense auxotrophic mutation in trpA of Escherichia coli, trpA218. The doubly mutant protein product differs from wild-type TrpA by the replacements of Phe22 by Leu and Gly211 by Ser. A partial revertant TrpA phenotype can be obtained from trpA218 by changing either Leu22 back to Phe or Ser211 back to Gly. Translational suppressors were previously obtained that act at codon 211, replacing the Ser211 in the TrpA218 protein, presumably with Gly. In the present study, we selected for trpA218 suppressors caused by mutation of a cloned tRNAPhe gene, pheV. DNA sequence analysis of the suppressor isolated reveals a singular structural alteration, changing the anticodon from 5'-GAA-3' to 5'-GAG-3'. Sequencing of trpA218 confirmed the likely identity of Leu22 as CUC. The new missense suppressor, designated pheV(SuCUC), is lethal to the cell when highly expressed, as from a high copy number plasmid. This may be due to efficient replacement of Leu by Phe at CUC (and, probably, CUU) codons throughout the genome. We anticipate that pheV(SuCUC) will prove, like other missense suppressors, to be extremely useful in studies on the specificity and accuracy of decoding.     

A single amino acid change in subunit 6 of the yeast mitochondrial ATPase suppresses a null mutation in ATP10

In an earlier study, the ATP10 gene of Saccharomyces cerevisiae was shown to code for an inner membrane protein required for assembly of the F(0) sector of the mitochondrial ATPase complex (Ackerman, S., and Tzagoloff, A. (1990) J. Biol. Chem. 265, 9952-9959). To gain additional insights into the function of Atp10p, we have analyzed a revertant of an atp10 null mutant that displays partial recovery of oligomycin-sensitive ATPase and of respiratory competence. The suppressor mutation in the revertant has been mapped to the OLI2 locus in mitochondrial DNA and shown to be a single base change in the C-terminal coding region of the gene. The mutation results in the substitution of a valine for an alanine at residue 249 of subunit 6 of the ATPase. The ability of the subunit 6 mutation to compensate for the absence of Atp10p implies a functional interaction between the two proteins. Such an interaction is consistent with evidence indicating that the C-terminal region with the site of the mutation and the extramembrane domain of Atp10p are both on the matrix side of the inner membrane. Subunit 6 has been purified from the parental wild type strain, from the atp10 null mutant, and from the revertant. The N-terminal sequences of the three proteins indicated that they all start at Ser(11), the normal processing site of the subunit 6 precursor. Mass spectral analysis of the wild type and mutants subunit 6 failed to reveal any substantive difference of the wild type and mutant proteins when the mass of the latter was corrected for Ala --> Val mutation. These data argue against a role of Atp10p in post-translational modification of subunit 6. Although post-translational modification of another ATPase subunit interacting with subunit 6 cannot be excluded, a more likely function for Atp10p is that it acts as a subunit 6 chaperone during F(0) assembly.     

Characterization of a suppressor mutation complementing an acid-sensitive mutation in Streptococcus mutans

We isolated a spontaneous suppressor mutant complementing the acid-sensitive phenotype of Streptococcus mutans strain Tn-1, a mutant previously generated in this laboratory, defective in the activity of the dgk-encoded putative undecaprenol kinase. A relatively simple genetic method was developed to identify the suppressor mutation, based on selection for transformants containing two closely linked markers: a selectable allele of the unknown suppressor gene and an antibiotic resistance gene introduced on a suicide plasmid at random sites into the chromosome via homologous recombination. While we have not actually identified the original suppressor mutation, another mutated gene restoring acid resistance has been isolated, which suggests a possible mechanism of suppression.     

Isolation and characterization of the putative nuclear modifier gene MTO1 involved in the pathogenesis of deafness-associated mitochondrial 12 S rRNA A1555G mutation

The human mitochondrial 12 S rRNA A1555G mutation has been found to be associated with aminoglycoside-induced and non-syndromic deafness. However, putative nuclear modifier gene(s) have been proposed to regulate the phenotypic expression of this mutation. In yeast, the mutant alleles of MTO1, encoding a mitochondrial protein, manifest respiratory-deficient phenotype only when coupled with the mitochondrial 15 S rRNA P(R)454 mutation corresponding to human A1555G mutation. This suggests that the MTO1-like modifier gene may influence the phenotypic expression of human A1555G mutation. Here we report the identification of full-length cDNA and elucidation of genomic organization of the human MTO1 homolog. Human Mto1 is an evolutionarily conserved protein that implicates a role in the mitochondrial tRNA modification. Functional conservation of this protein is supported by the observation that isolated human MTO1 cDNA can complement the respiratory deficient phenotype of yeast mto1 cells carrying P(R)454 mutation. MTO1 is ubiquitously expressed in various tissues, but with a markedly elevated expression in tissues of high metabolic rates including cochlea. These observations suggest that human MTO1 is a structural and functional homolog of yeast MTO1. Thus, it may play an important role in the pathogenesis of deafness-associated A1555G mutation in 12 S rRNA gene or mutations in tRNA genes.     

A novel type of + 1 frameshift suppressor: a base substitution in the anticodon stem of a yeast mitochondrial serine-tRNA causes frameshift suppression.

We have identified a spontaneous mitochondrial mutation, mfs-1 (mitochondrial frameshift suppressor-1), which suppresses a + 1 frameshift mutation localized in the yeast mitochondrial oxi1 gene. The suppressor strain exhibits a single base change (C to U) at position 42 of the mitochondrial serine-tRNA (UCN). To our knowledge, this is the first reported case showing that a mutation in the anticodon stem of a tRNA can cause frameshift suppression. The expression and aminoacylation of the mutant tRNASer(UCN) are not significantly affected. However, the base change at position 42 has two effects: first, residue U27 of the mutant tRNA is not modified to pseudouridine as observed in wild-type tRNASer(UCN). Second, the base change and/or the lack of modification of U27 leads to an alteration in the secondary/tertiary structure of the mutant tRNA. It is possible that there are such structural changes in the anticodon loop that enable the tRNA to read a four base codon, UCCA, thus restoring the wild-type reading frame.     

A mutation in a methionine tRNA gene suppresses the prp2-1 Ts mutation and causes a pre-mRNA splicing defect in Saccharomyces cerevisiae.

The PRP2 gene in Saccharomyces cerevisiae encodes an RNA-dependent ATPase that activates spliceosomes for the first transesterification reaction in pre-mRNA splicing. We have identified a mutation in the elongation methionine tRNA gene EMT1 as a dominant, allele-specific suppressor of the temperature-sensitive prp2-1 mutation. The EMT1-201 mutant suppressed prp2-1 by relieving the splicing block at high temperature. Furthermore, EMT1-201 single mutant cells displayed pre-mRNA splicing and cold-sensitive growth defects at 18 degrees. The mutation in EMT1-201 is located in the anticodon, changing CAT to CAG, which presumably allowed EMT1-201 suppressor tRNA to recognize CUG leucine codons instead of AUG methionine codons. Interestingly, the prp2-1 allele contains a point mutation that changes glycine to aspartate, indicating that EMT1-201 does not act by classical missense suppression. Extra copies of the tRNA(Leu)(UAG) gene rescued the cold sensitivity and in vitro splicing defect of EMT1-201. This study provides the first example in which a mutation in a tRNA gene confers a pre-mRNA processing (prp) phenotype.     

Genetic analysis of a temperature-sensitive Salmonella typhimurium rho mutant with an altered rho-associated polycytidylate-dependent adenosine triphosphatase activity.

A conditional-lethal rho mutant of Salmonella typhimurium LT2 has been isolated. The mutation was selected as a suppressor of the polarity of an insertion sequence (IS)2-induced mutation (gal3) carried on an F' plasmid. In addition to suppression of IS2-induced polarity, the rho-111 mutation suppressed nonsense and frameshift polarity. The rho-associated polycytidylic acid-dependent adenosine triphosphatase activity in the mutant strain was elevated 15-fold above that in the parental strain, and the mutant rho protein was thermally unstable. A temperature-resistant revertant of the mutant strain did not suppress polarity and contained normal levels of polycytidylic acid-dependent adenosine triphosphatase, suggesting that the phenotype of the rho-111-bearing strain is the consequence of a single mutation. The rho-111 mutation was located on the S. typhimurium linkage map midway between the ilv and cya loci by phage P22 cotransduction studies. F' plasmid maintenance was not impaired in the mutant strain, and the mutation was recessive to the wild-type allele. The rho-111 mutation did not alter in vivo expression of either the tryptophan or histidine operons.     

Pathogenesis of the deafness-associated A1555G mitochondrial DNA mutation

The pathogenic mechanisms of the A1555G mitochondrial DNA mutation in the 12S rRNA gene, associated with maternally inherited sensorineural deafness, are largely unknown. Previous studies have suggested an involvement of nuclear factor(s). To address this issue cybrids were generated by fusing osteosarcoma cells devoid of mtDNA with enucleated fibroblasts from two genetically unrelated patients. Furthermore, to determine the contribution, if any, of the mitochondrial and nuclear genomes, separately or in combination, in the expression of the disease phenotype, transmitochondrial fibroblasts were constructed using control and patient's fibroblasts as nuclear donors and homoplasmic mutant or wild-type cybrids as mitochondrial donors. Detailed analysis of mutant and wild-type cybrids from both patients and transmitochondrial fibroblast clones did not reveal any respiratory chain dysfunction suggesting that, if nuclear factors do indeed act as modifier agents, they may be tissue-specific. However, in the presence of high concentrations of neomycin or paromomycin, but not of streptomycin, mutant cells exhibit a decrease in the growth rate, when compared to wild-type cells. The decrease did not correlate with the rate of synthesis or stability of mitochondrial DNA-encoded subunits or respiratory chain activity. Further studies are required to determine the underlying biochemical defect.