At least two nuclear gene products are specifically required for translation of a single yeast mitochondrial mRNA.

Mitochondrial translation of the oxi2 mRNA, encoding yeast cytochrome c oxidase subunit III (coxIII), has previously been shown to specifically require the mitochondrially located protein product of the nuclear gene PET494. We show here that this specific translational activation involves at least one other newly identified gene termed PET54. Mutations in PET54 cause an absence of the coxIII protein despite the presence of normal levels of its mRNA. pet494 mutations are known to be suppressible by mitochondrial gene rearrangements that replace the normal 5'-untranslated leader of the oxi2 mRNA with the leaders of other mitochondrial mRNAs. In this study we show that pet54, pet494 double mutants are suppressed by the same mitochondrial gene rearrangements, showing that the PET54 product is specifically required, in addition to the PET494 protein, for translation of the oxi2 mRNA. Since, as we show here, PET54 is not an activator of PET494 gene expression, our results suggest that the products of both of these genes may act together to stimulate coxIII translation.     

Pet111 Acts in the 5''-Leader of the Saccharomyces Cerevisiae Mitochondrial Cox2 mRNA to Promote Its Translation

PET111 is a yeast nuclear gene specifically required for the expression of the mitochondrial gene COX2, encoding cytochrome c oxidase subunit II (coxII). Previous studies have shown that PET111 activates translation of the COX2 mRNA. To map the site of PET111 action we have constructed, in vitro, genes coding for chimeric mRNAs, introduced them into mitochondria by transformation and studied their expression. Translation of a chimeric mRNA with the 612-base 5'-untranslated leader of the COX3 mRNA fused precisely to the structural gene for the coxII-precursor protein is independent of PET111, but does require a COX3 mRNA-specific translational activator known to work on the COX3 5'-leader. This result demonstrates that PET111 is not required for any posttranslational step. Translation of a chimeric mRNA with the 54-base 5'-leader of the COX2 mRNA fused precisely to the structural gene for cytochrome c oxidase subunit III was dependent on PET111 activity. These results demonstrate that PET111 acts specifically at a site in the short COX2 5'-leader to activate translation of downstream coding sequences.     

A Genetic Link between an mRNA-Specific Translational Activator and the Translation System in Yeast Mitochondria

Translation of the Saccharomyces cerevisiae mitochondrial mRNA encoding cytochrome c oxidase subunit III (coxIII) specifically requires the products of at least three nuclear genes, PET122, PET494 and PET54. pet122 mutations that remove 24-67 amino acid residues from the carboxyterminus of the gene product were found to be suppressed by unlinked nuclear mutations. These unlinked suppressors fail to suppress both a pet122 missense mutation and a complete pet122 deletion. One of the suppressor mutations causes a heat-sensitive nonrespiratory growth phenotype in an otherwise wild-type strain and reduces translation of all mitochondrial gene products in cells grown at high temperature. This suppressor maps to a newly identified gene on chromosome XV termed PET123. The sequence of a DNA fragment carrying PET123 contains one major open reading frame encoding a basic protein of 318 amino acids. Inactivation of the chromosomal copy of PET123 by interruption of this open reading frame causes cells to become rho- (sustain large deletions in their mtDNA). This phenotype is characteristic for null alleles of genes whose products are essential for general mitochondrial protein synthesis. Thus our data strongly suggest that the PET123 protein is a component of the mitochondrial translation apparatus that interacts directly with the coxIII-mRNA-specific translational activator PET122.     

Functional Interactions among Two Yeast Mitochondrial Ribosomal Proteins and an mRNA-Specific Translational Activator

Expression of the Saccharomyces cerevisiae mitochondrial gene coding cytochrome c oxidase subunit III is specifically activated at the level of translation by at least three nuclear genes, PET122, PET494 and PET54. We have shown previously that carboxy-terminal deletions of PET122 are allele-specifically suppressed by mutations in an unlinked nuclear gene, termed PET123, that encodes a small subunit ribosomal protein. Here we describe additional pet122 suppressors generated by mutations in a second gene which we show to be the previously identified nuclear gene MRP1. Like PET123, MRP1 encodes a component of the small subunit of mitochondrial ribosomes. Our mrp1 mutations are allele-specific suppressors of carboxyl-terminal truncations of the PET122 protein and do not bypass the requirement for residual function of PET122. None of our mrp1 mutations has an intrinsic phenotype in an otherwise wild-type background. However, some of the mrp1 mutations cause a non-conditional respiratory-defective phenotype in combination with certain pet123 alleles. This synthetic defective phenotype suggests that the ribosomal proteins PET123 and MRP1 interact functionally with each other. The fact that they can both mutate to suppress certain alleles of the mRNA-specific translational activator PET122 strongly suggests that the PET122 protein promotes translation of the coxIII mRNA via an interaction with the small subunit of mitochondrial ribosomes.     

A novel small-subunit ribosomal protein of yeast mitochondria that interacts functionally with an mRNA-specific translational activator.

Mitochondrial translation of the mRNA encoding cytochrome c oxidase subunit III (coxIII) specifically requires the action of three position activator proteins encoded in the nucleus of Saccharomyces cerevisiae. Some mutations affecting one of these activators, PET122, can be suppressed by mutations in an unlinked nuclear gene termed PET123. PET123 function was previously demonstrated to be required for translation of all mitochondrial gene products. We have now generated an antibody against the PET123 protein and have used it to demonstrate that PET123 is a mitochondrial ribosomal protein of the small subunit. PET123 appears to be present at levels comparable to those of other mitochondrial ribosomal proteins, and its accumulation is dependent on the presence of the 15S rRNA gene in mitochondria. Taken together with the previous genetic data, these results strongly support a model in which the mRNA-specific translational activator PET122 works by directly interacting with the small ribosomal subunit to promote translation initiation on the coxIII mRNA.     

The yeast nuclear gene CBS1 is required for translation of mitochondrial mRNAs bearing the cob 5'' untranslated leader

Summary Mitochondrial translation of the cob mRNA to yield apocytochrome b is specifically dependent on the nuclear gene CBS1, while mitochondrial translation of the oxi2 mRNA to yield cytochrome oxidase subunit III (cox III) is specifically dependent on the nuclear gene PET494. Chimeric oxi2 mRNAs bearing the 5 leaders of other mitochondrial mRNAs, transcribed from rho ^- mitochondrial DNAs termed MSU494, are translated in pet494 mutants. In this study, we examined translation of coxIII from MSU494-encoded chimeric mRNAs in zygotes of defined nuclear and mitochondrial genotype. CoxIII was translated from a chimeric mRNA bearing the cob leader only when the zygotes contained a wild-type CBS1 gene. CoxIII translation from an mRNA bearing the 5 leader of the mitochondrial gene aap1 was not dependent on CBS1 activity. We conclude that the product of the nuclear gene CBS1, or something under its control, acts in the mitochondrion on the cob mRNA 5 leader to activate translation of downstream coding sequences.     

Site-Directed Mutagenesis of a Saccharomyces Cerevisiae Mitochondrial Translation Initiation Codon

We have used a generally applicable strategy for gene replacement in yeast mitochondria to mutate the translation initiation codon of the COX3 gene from AUG to AUA. The mutation, cox3-1, substantially reduced, but did not eliminate, translation of cytochrome c oxidase subunit III (coxIII). Strains bearing the mutation exhibited a leaky (partial) nonrespiratory growth phenotype and a reduced incorporation of radiolabeled amino acids into coxIII in vivo in the presence of cycloheximide. Hybridization experiments demonstrated that the mutation had little or no effect on levels of the COX3 mRNA. Residual translation of the cox3-1 mutant mRNA was dependent upon the three nuclearly coded mRNA-specific activators PET494, PET54 and PET122, known from previous studies to work through a site (or sites) upstream of the initiation codon to promote translation of the wild-type mRNA. Furthermore, respiratory growth of cox3-1 mutant strains was sensitive to decreased dosage of genes PET494 and PET122 in heterozygous mutant diploids, unlike the growth of strains carrying wild-type mtDNA. Some residual translation of the cox3-1 mRNA appeared to initiate at the mutant AUA codon, despite the fact that the 610-base 5'-mRNA leader contains numerous AUA triplets. We conclude that, while AUG is an important component of the COX3 translation initiation site, the site probably is also specified by other sequence or structural features.     

Highly diverged homologs of Saccharomyces cerevisiae mitochondrial mRNA-specific translational activators have orthologous functions in other budding yeasts

Translation of mitochondrially coded mRNAs in Saccharomyces cerevisiae depends on membrane-bound mRNA-specific activator proteins, whose targets lie in the mRNA 5'-untranslated leaders (5'-UTLs). In at least some cases, the activators function to localize translation of hydrophobic proteins on the inner membrane and are rate limiting for gene expression. We searched unsuccessfully in divergent budding yeasts for orthologs of the COX2- and COX3-specific translational activator genes, PET111, PET54, PET122, and PET494, by direct complementation. However, by screening for complementation of mutations in genes adjacent to the PET genes in S. cerevisiae, we obtained chromosomal segments containing highly diverged homologs of PET111 and PET122 from Saccharomyces kluyveri and of PET111 from Kluyveromyces lactis. All three of these genes failed to function in S. cerevisiae. We also found that the 5'-UTLs of the COX2 and COX3 mRNAs of S. kluyveri and K. lactis have little similarity to each other or to those of S. cerevisiae. To determine whether the PET111 and PET122 homologs carry out orthologous functions, we deleted them from the S. kluyveri genome and deleted PET111 from the K. lactis genome. The pet111 mutations in both species prevented COX2 translation, and the S. kluyveri pet122 mutation prevented COX3 translation. Thus, while the sequences of these translational activator proteins and their 5'-UTL targets are highly diverged, their mRNA-specific functions are orthologous.     

In vivo analysis of mutated initiation codons in the mitochondrial COX2 gene of Saccharomyces cerevisiae fused to the reporter gene ARG8m reveals lack of downstream reinitiation

To examine normal and aberrant translation initiation in Saccharomyces cerevisiae mitochondria, we fused the synthetic mitochondrial reporter gene ARG8m to codon 91 of the COX2 coding sequence and inserted the chimeric gene into mitochondrial DNA (mtDNA). Translation of the cox2(1-91)::ARG8m mRNA yielded a fusion protein precursor that was processed to yield wild-type Arg8p. Thus mitochondrial translation could be monitored by the ability of mutant chimeric genes to complement a nuclear arg8 mutation. As expected, translation of the cox2(1-91)::ARG8m mRNA was dependent on the COX2 mRNA-specific activator PET111. We tested the ability of six triplets to function as initiation codons in both the cox2(1-91)::ARG8m reporter mRNA and the otherwise wild-type COX2 mRNA. Substitution of AUC, CCC or AAA for the initiation codon abolished detectable translation of both mRNAs, even when PET111 activity was increased. The failure of these mutant cox2(1-91)::ARG8m genes to yield Arg8p demonstrates that initiation at downstream AUG codons, such as COX2 codon 14, does not occur even when normal initiation is blocked. Three mutant triplets at the site of the initiation codon supported detectable translation, with efficiencies decreasing in the order GUG, AUU, AUA. Increased PET111 activity enhanced initiation at AUU and AUA codons. Comparisons of expression, at the level of accumulated product, of cox2(1-91)::ARG8m and COX2 carrying these mutant initiation codons revealed that very low-efficiency translation can provide enough Cox2p to sustain significant respiratory growth, presumably because Cox2p is efficiently assembled into stable cytochrome oxidase complexes.     

Cytochrome aa3 of Rhodobacter sphaeroides as a model for mitochondrial cytochrome c oxidase. The coxII/coxIII operon codes for structural and assembly proteins homologous to those in yeast.

The coxII/coxIII operon of Rhodobacter sphaeroides cytochrome c oxidase has been sequenced and characterized by insertional inactivation/complementation analysis. The organization of the genes in this locus (coxII.orf1.orf3.coxIII) is the same as that of the equivalent operon of Paracoccus denitrificans (ctaC.ctaB.ctaG.ctaE), but unlike that of other bacteria whose cytochrome oxidase genes have been characterized so far. The predicted amino acid sequence homology with eukaryotic oxidases is also higher for Rb. sphaeroides (and P. denitrificans) than for other bacterial versions of the enzyme. The inactivation of coxII results in loss of the characteristic cytochrome oxidase spectrum from membranes of the mutant strain. Full recovery requires introduction into the bacterium of the complete operon containing coxII.orf1.orf3.coxIII; partial complementation yielding a spectrally altered enzyme is achieved with a plasmid containing coxII or coxII.orf1.orf3. These results indicate that the peptides ORF1, ORF3, and COXIII are all required for assembly of native cytochrome c oxidase, suggesting an oxidase-specific assembly or chaperonin function for the ORFs in Rb. sphaeroides similar to that observed for the homologous gene products in yeast, COX10 and COX11.     

Analysis of the Saccharomyces cerevisiae mitochondrial COX3 mRNA 5' untranslated leader: translational activation and mRNA processing.

We used transformation of yeast mitochondria and homologous gene replacement to study features of the 613-base COX3 mRNA 5' untranslated leader (5'-UTL) required for translational activation by the protein products of the nuclear genes PET54, PET122, and PET494 in vivo. Elimination of the single AUG triplet in the 5'-UTL had no detectable effect on expression, indicating that activator proteins do not work by allowing ribosomes to bypass that AUG. Deletion of the entire 5'-UTL completely prevented translation, suggesting that the activator proteins do not function by antagonizing any other negative element in the 5'-UTL. Removal of the 15 terminal bases from the 5' end of the 5'-UTL did not block activator-dependent translation. The largest internal deletion that did not interfere with translation removed 125 bases from the upstream portion of the leader. However, two large deletions that blocked translation could be reverted to activator-dependent expression by secondary changes in the remaining 5'-UTL sequences, indicating that the original deletions had not removed the translational activator target but only deformed it. Taken together, the deletion mutations and revertants define a region of 151 bases (between positions -480 and -330 relative to the start codon) containing sequences that are sufficient for translational activation when modified slightly. Suppression of the respiratory phenotypes of two 5'-UTL mutations by overexpression of PET54, PET122, and PET494 indicated functional interactions between the leader and the three activator proteins. The mature COX3 mRNA is cleaved from a precursor immediately downstream of the preceding tRNAVal in a fashion resembling mRNA processing in vertebrate mitochondria. Our results indicate that the site of this cleavage in Saccharomyces cerevisiae is determined solely by the position of the tRNA.     

Alteration of a novel dispensable mitochondrial ribosomal small-subunit protein, Rsm28p, allows translation of defective COX2 mRNAs

Mutations affecting the RNA sequence of the first 10 codons of the Saccharomyces cerevisiae mitochondrial gene COX2 strongly reduce translation of the mRNA, which encodes the precursor of cytochrome c oxidase subunit II. A dominant chromosomal mutation that suppresses these defects is an internal in-frame deletion of 67 codons from the gene YDR494w. Wild-type YDR494w encodes a 361-residue polypeptide with no similarity to proteins of known function. The epitope-tagged product of this gene, now named RSM28, is both peripherally associated with the inner surface of the inner mitochondrial membrane and soluble in the matrix. Epitope-tagged Rsm28p from Triton X-100-solubilized mitochondria sedimented with the small subunit of mitochondrial ribosomes in a sucrose gradient containing 500 mM NH4Cl. Complete deletion of RSM28 caused only a modest decrease in growth on nonfermentable carbon sources in otherwise wild-type strains and enhanced the respiratory defect of the suppressible cox2 mutations. The rsm28 null mutation also reduced translation of an ARG8m reporter sequence inserted at the COX1, COX2, and COX3 mitochondrial loci. We tested the ability of RSM28-1 to suppress a variety of cox2 and cox3 mutations and found that initiation codon mutations in both genes were suppressed. We conclude that Rsm28p is a dispensable small-subunit mitochondrial ribosomal protein previously undetected in systematic investigations of these ribosomes, with a positive role in translation of several mitochondrial mRNAs.     

Apoptotic role of TGF-β mediated by Smad4 mitochondria translocation and cytochrome c oxidase subunit II interaction

Smad4, originally isolated from the human chromosome 18q21, is a key factor in transducing the signals of the TGF-β superfamily of growth hormones and plays a pivotal role in mediating antimitogenic and proapoptotic effects of TGF-β, but the mechanisms by which Smad4 induces apoptosis are elusive. Here we report that Smad4 directly translocates to the mitochondria of apoptotic cells. Smad4 gene silencing by siRNA inhibits TGF-β-induced apoptosis in Hep3B cells and UV-induced apoptosis in PANC-1 cells. Cell fractionation assays demonstrated that a fraction of Smad4 translocates to mitochondria after long time TGF-β treatment or UV exposure, during which the cells were under apoptosis. Smad4 mitochondria translocation during apoptosis was also confirmed by fluorescence observation of Smad4 colocalization with MitoTracker Red. We searched for mitochondria proteins that have physical interactions with Smad4 using yeast two-hybrid screening approach. DNA sequence analysis identified 34 positive clones, five of which encoded subunits in mitochondria complex IV, i.e., one clone encoded cytochrome c oxidase COXII, three clones encoded COXIII and one clone encoded COXVb. Strong interaction between Smad4 with COXII, an important apoptosis regulator, was verified in yeast by β-gal activity assays and in mammalian cells by immunoprecipitation assays. Further, mitochondrial portion of cells was isolated and the interaction between COXII and Smad4 in mitochondria upon TGF-β treatment or UV exposure was confirmed. Importantly, targeting Smad4 to mitochondria using import leader fusions enhanced TGF-β-induced apoptosis. Collectively, the results suggest that Smad4 promote apoptosis of the cells through its mitochondrial translocation and association with mitochondria protein COXII.     

A 40 kd protein binds specifically to the 5''-untranslated regions of yeast mitochondrial mRNAs.

Using a gel mobility shift assay we show that a 40 kd protein (p40), present in extracts of yeast mitochondria, binds specifically to the 5'-untranslated leader of cytochrome c oxidase subunit II mRNA. Binding of p40 to coxII RNA protects an 8-10 nucleotide segment from diethylpyocarbonate modification, indicating that the protein interacts with only a restricted region of the 5'-leader. This segment is located at position -12 with respect to the initiation AUG. Deletion of 10 nucleotides encompassing this site completely abolishes protein binding. Nevertheless, Bal31 deletion analysis within the coxII leader shows that a major part of the leader is essential for p40 binding, suggesting that binding of the protein is also dependent on secondary structural features. p40 binds to other mitochondrial leader mRNAs including those for coxI, coxIII and cyt b. p40 is present in a cytoplasmic (rho0) petite mutant lacking mitochondrial protein synthesis. It is therefore presumably nuclear encoded. The possible biological function of the protein is discussed.