Genetic evidence for interaction between Cbp1 and specific nucleotides in the 5' untranslated region of mitochondrial cytochrome b mRNA in Saccharomyces cerevisiae.

The cytochrome b (COB) gene is encoded by the mitochondrial genome; however, its expression requires the participation of several nuclearly encoded protein factors. The yeast Cbp1 protein, which is encoded by the nuclear CBP1 gene, is required for the stabilization of COB mRNA. A previous deletion analysis identified an 11-nucleotide-long sequence within the 5' untranslated region of COB mRNA that is important for Cbp1-dependent COB mRNA stability. In the present study, site-directed mutagenesis experiments were carried out to define further the features of this cis element. The CCG sequence within this region was shown to be necessary for stability. A change in residue 533 of Cbp1 from aspartate to tyrosine suppresses the effects of a single-base change in the CCG element. This is strong genetic evidence that the nuclearly encoded Cbp1 protein recognizes and binds directly to the sequence containing CCG and thus protects COB mRNA from degradation.     

Suppressor analysis of mutations in the 5'-untranslated region of COB mRNA identifies components of general pathways for mitochondrial mRNA processing and decay in Saccharomyces cerevisiae

The cytochrome b gene in Saccharomyces cerevisiae, COB, is encoded by the mitochondrial genome. Nuclear-encoded Cbp1 protein is required specifically for COB mRNA stabilization. Cbp1 interacts with a CCG element in a 64-nucleotide sequence in the 5'-untranslated region of COB mRNA. Mutation of any nucleotide in the CCG causes the same phenotype as cbp1 mutations, i.e., destabilization of both COB precursor and mature message. In this study, eleven nuclear suppressors of single-nucleotide mutations in CCG were isolated and characterized. One dominant suppressor is in CBP1, while the other 10 semidominant suppressors define five distinct linkage groups. One group of four mutations is in PET127, which is required for 5' end processing of several mitochondrial mRNAs. Another mutation is linked to DSS1, which is a subunit of mitochondrial 3' --> 5' exoribonuclease. A mutation linked to the SOC1 gene, previously defined by recessive mutations that suppress cbp1 ts alleles and stabilize many mitochondrial mRNAs, was also isolated. We hypothesize that the products of the two uncharacterized genes also affect mitochondrial RNA turnover.     

Ribosome binding to the Oxa1 complex facilitates co-translational protein insertion in mitochondria

The Oxa1 translocase of the mitochondrial inner membrane facilitates the insertion of both mitochondrially and nuclear-encoded proteins from the matrix into the inner membrane. Most mitochondrially encoded proteins are hydrophobic membrane proteins which are integrated into the lipid bilayer during their synthesis on mitochondrial ribosomes. The molecular mechanism of this co-translational insertion process is unknown. Here we show that the matrix-exposed C-terminus of Oxa1 forms an alpha-helical domain that has the ability to bind to mitochondrial ribosomes. Deletion of this Oxa1 domain strongly diminished the efficiency of membrane insertion of subunit 2 of cytochrome oxidase, a mitochondrially encoded substrate of the Oxa1 translocase. This suggests that co-translational membrane insertion of mitochondrial translation products is facilitated by a physical interaction of translation complexes with the membrane-bound translocase.     

A yeast mitochondrial inner membrane 30K hydrophobic protein: comparison with subunit 32K of the cytochrome BC 1 complex

A yeast mitochondrial inner membrane hydrophobic protein 30K has been isolated and compared to subunit 32K of the yeast cytochrome bc 1 complex. Both proteins are translated on mitochondrial ribosomes, have nearly the same molecular weight and similar aminoacid compositions. Comparison was carried out by immunological techniques with specific antibodies, and by studying 3 yeast strains having mutations in the COB region of the mitochondrial DNA. Results show that the two proteins are not identical.     

TbDSS-1, an essential Trypanosoma brucei exoribonuclease homolog that has pleiotropic effects on mitochondrial RNA metabolism

Mitochondrial gene expression in trypanosomes is controlled primarily at the levels of RNA processing and RNA stability. This regulation undoubtedly involves numerous ribonucleases. Here we characterize the Trypanosoma brucei homolog of the yeast DSS-1 mitochondrial exoribonuclease, which we term TbDSS-1. Biochemical fractionation indicates that TbDSS-1 is mitochondrially localized, as predicted by its N-terminal sequence. In contrast to its yeast homolog, TbDSS-1 does not appear to be associated with mitochondrial ribosomes. Targeted downregulation of TbDSS-1 by RNA interference in procyclic-form T. brucei results in a severe growth defect. In addition, TbDSS-1 depletion leads to a decrease in the levels of never edited cytochrome oxidase subunit I (COI) mRNA and both unedited and edited COIII mRNAs, indicating this enzyme functions in the control of mitochondrial RNA abundance. We also observe a considerable reduction in the level of edited apocytochrome b (CYb) mRNA and a corresponding increase in unedited CYb mRNA, suggesting that TbDSS-1 functions, either directly or indirectly, in the control of RNA editing. The abundance of both gCYb[560] and gA6[149] guide RNAs is reduced upon TbDSS-1 depletion, although the reduction in gCYb[560] is much more dramatic. The significant reduction in gCYb levels could potentially account for the observed decrease in CYb RNA editing. Western blot analyses of mitochondrial RNA editing and stability factors indicate that the perturbations of RNA levels observed in TbDSS-1 knock-downs do not result from secondary effects on other mitochondrial proteins. In all, these data demonstrate that TbDSS-1 is an essential protein that plays a role in mitochondrial RNA stability and RNA editing.     

High-mobility group A1 protein inhibits p53-mediated intrinsic apoptosis by interacting with Bcl-2 at mitochondria

The high-mobility group A (HMGA) proteins are a family of non-histone chromatin factors, encoded by the HMGA1 and HMGA2 genes. Several studies demonstrate that HMGA proteins have a critical role in neoplastic transformation, and their overexpression is mainly associated with a highly malignant phenotype, also representing a poor prognostic index. Even though a cytoplasmic localization of these proteins has been previously reported in some highly malignant neoplasias, a clear role for this localization has not been defined. Here, we first confirm the localization of the HMGA1 proteins in the cytoplasm of cancer cells, and then we report a novel mechanism through which HMGA1 inhibits p53-mitochondrial apoptosis by counteracting the binding of p53 to the anti-apoptotic factor Bcl-2. Indeed, we demonstrate a physical and functional interaction between HMGA1 and Bcl-2 proteins. This interaction occurs at mitochondria interfering with the ability of p53 protein to bind Bcl-2, thus counteracting p53-mediated mitochondrial apoptosis. This effect is associated with the inhibition of cytochrome c release and activation of caspases. Consistent with this mechanism, a strong correlation between HMGA1 cytoplasmic localization and a more aggressive histotype of thyroid, breast and colon carcinomas has been observed. Therefore, cytoplasmic localization of HMGA1 proteins in malignant tissues is a novel mechanism of inactivation of p53 apoptotic function.     

Antibodies against a fused ''lacZ-yeast mitochondrial intron'' gene product allow identification of the mRNA maturase encoded by the fourth intron of the yeast cob-box gene.

Several missense or nonsense mutations have been localized in the fourth intron open reading frame (ORF) of the yeast mitochondrial cytochrome b gene. These results and the phenotypes of mutants strongly suggested that a mRNA maturase, controlling the expression of both cytochrome b and cytochrome oxidase subunit I (COXI) genes, is encoded in this ORF. To investigate more directly the biosynthesis of mRNA maturase we raised antibodies against a part of the putative ORF translation product. For that purpose we inserted a fragment of the ORF sequence, in phase, into the C-terminal EcoRI site of lacZ gene. The hybrid gene was then expressed in Escherichia coli under the control of either the wild-type lac promoter or the thermoregulated lambda system PR/cI857. The hybrid protein was partially purified and antibodies were raised against it. These antibodies recognized a mitochondrially coded protein, p27, in intron mutants, whereas no such protein was detected in the wild-type cell. These results demonstrate that the p27 protein, previously shown to be associated with the mRNA maturase activity, is actually translated from the intron ORF. The autoregulated mRNA maturase synthesis model is discussed in relation to these results.     

The identification of apocytochrome b as a mitochondrial gene product and immunological evidence for altered apocytochrome b in yeast strains having mutations in the COB region of mitochondrial DNA.

The yeast mitochondrial translation product of Mr 30 000 is identical with apocytochrome b. After labelling in vivo with [35S]sulphate in the presence of cycloheximide, the radioactivity in this product present in solubilized submitochondrial particles, was completely recovered in pure cytochrome bc1 complex as a single polypeptide. We show that this translation product is identical with apocytochrome b using peptide mapping by limited proteolysis according to Cleveland et al. [J. Biol. Chem. 250 (1977) 8236-8242] and by immunoprecipitation with a specific antiserum against apocytochrome b. New mitochondrial translation products in 36 strains of Saccharomyces cerevisiae having mutations in the COB region of the mitochondrial DNA, are precipitated by this antiserum. This is consistent with the assumption that many of the cob mutations are localized in the structural gene for apolcytochrome b on mitochondrial DNA. Mutations in two intervening sequences can give rise to products related to apocytochrome b that are considerably longer than normal apocytochrome b. We discuss the hypothesis that in these mutants splicing of the messenger RNA does not occur correctly and that, as a consequence of this, ribosomes read through in an intervening sequence.     

Editing of the grapevine mitochondrial cytochrome b mRNA and molecular modeling of the protein

Cytochrome b (COB), the central catalytic subunit of ubiquinol cytochrome c reductase, is a component of the transmembrane electron transfer chain that generates proton motive force. Some plant COB mRNAs are processed by RNA editing, which changes the gene coding sequence. This report presents the sequences of the grapevine (Vitis vinifera L.) mitochondrial gene for apocytochrome b (cob), the edited mRNA and the deduced protein. Grapevine COB is 393 amino acids long and is 98% identical to homologs in rapeseed, Arabidopsis thaliana and Oenothera sp. Twenty-one C-U editing sites were identified in the grapevine cob mRNA, resulting in 20 amino acid changes. These changes increase the overall hydrophobicity of the protein and result in a more conserved protein. Molecular modeling of grapevine COB shows that residues changed by RNA editing fit the secondary structure characteristic of an integral membrane protein. This is the first complete mitochondrial gene reported for grapevine. Novel RNA editing sites were identified in grapevine cob, which have not been previously reported for other plants.     

Trypanosoma brucei cytochrome c1 is imported into mitochondria along an unusual pathway

In most eukaryotic organisms, cytochrome c(1) is encoded in the nucleus, translated on cytosolic ribosomes, and directed to its final destination in the mitochondrial inner membrane by a bipartite, cleaved, amino-terminal presequence. However, in the kinetoplastids and euglenoids, the cytochrome c(1) protein has been shown to lack a cleaved presequence; a single methionine is removed from the amino terminus upon maturation, and the sequence upstream of the heme-binding site is generally shorter than that of the other eukaryotic homologs. We have used a newly developed mitochondrial protein import assay system from Trypanosoma brucei to demonstrate that the T. brucei cytochrome c(1) protein is imported along a non-conservative pathway similar to that described for the inner membrane carrier proteins of other organisms. This pathway requires external ATP and an external protein receptor but is not absolutely dependent on a membrane potential or on ATP hydrolysis in the mitochondrial matrix. We propose the cytochrome c(1) import in T. brucei is a two-step process first involving a membrane potential independent translocation across the outer mitochondrial membrane followed by heme attachment and a membrane potential-dependent insertion into the inner membrane.     

Generation of Temperature-Sensitive Cbp1 Strains of Saccharomyces Cerevisiae by Pcr Mutagenesis and in Vivo Recombination: Characteristics of the Mutant Strains Imply That Cbp1 Is Involved in Stabilization and Processing of Cytochrome B Pre-mRNA

Mitochondrial biogenesis is dependent on both nuclearly and mitochondrially encoded proteins. Study of the nuclearly encoded mitochondrial gene products and their effect on mitochondrial genome expression is essential to understanding mitochondrial function. Mutations in the nuclear gene CBP1 of Saccharomyces cerevisiae result in degradation of mitochondrially encoded cytochrome b (cob) RNA; thus, the cells are unable to respire. Putative roles for the CBP1 protein include processing of precursor RNA to yield the mature 5' end of cob mRNA and/or physical protection of the mRNA from degradation by nucleases. To examine the activity of CBP1, we generated temperature-sensitive cbp1 mutant strains by polymerase chain reaction (PCR) mutagenesis and in vivo recombination. These temperature-sensitive cbp1 strains lack cob mRNA only at the nonpermissive temperature. Quantitative primer extension analyses of RNA from these strains and from a cbp1 deletion strain demonstrated that CBP1 is required for the stability of precursor RNAs in addition to production of the stable mature mRNA. Thus, CBP1 is not involved solely in the protection of mature cob mRNA from nucleases. Moreover, we found that mature mRNAs are undetectable while precursor RNAs are reduced only slightly at the nonpermissive temperature. Collectively, these data lead us to favor a hypothesis whereby CBP1 protects cob precursor RNAs and promotes the processing event that generates the mature 5' end of the mRNA.     

Interactions among COX1, COX2, and COX3 mRNA-specific translational activator proteins on the inner surface of the mitochondrial inner membrane of Saccharomyces cerevisiae

The core of the cytochrome c oxidase complex is composed of its three largest subunits, Cox1p, Cox2p, and Cox3p, which are encoded in mitochondrial DNA of Saccharomyces cerevisiae and inserted into the inner membrane from the inside. Mitochondrial translation of the COX1, COX2, and COX3 mRNAs is activated mRNA specifically by the nuclearly coded proteins Pet309p, Pet111p, and the concerted action of Pet54p, Pet122p, and Pet494p, respectively. Because the translational activators recognize sites in the 5'-untranslated leaders of these mRNAs and because untranslated mRNA sequences contain information for targeting their protein products, the activators are likely to play a role in localizing translation. Herein, we report physical associations among the mRNA-specific translational activator proteins, located on the matrix side of the inner membrane. These interactions, detected by coimmune precipitation and by two-hybrid experiments, suggest that the translational activator proteins could be organized on the surface of the inner membrane such that synthesis of Cox1p, Cox2p, and Cox3p would be colocalized in a way that facilitates assembly of the core of the cytochrome c oxidase complex. In addition, we found interactions between Nam1p/Mtf2p and the translational activators, suggesting an organized delivery of mitochondrial mRNAs to the translation system.     

The mitochondrial COB region in yeast codes for apocytochrome b and is mosaic.

Mitochondrial mutants of Saccharomyces cerevisiae defective in cytochrome b were analyzed genetically and biochemically in order to elucidate the role of the mitochondrial genetic system in the biosynthesis of this cytochrome. The mutants mapped between OLI1 and OLI2 on mitochondrial DNA in a region called COB. A fine structure map of the COB region was constructed by rho- deletion mapping and recombination analysis. The combined genetic and biochemical data indicate that the COB region is mosaic and contains at least five distinct clusters of mutants, A-E, with A being closest to OLI2 and E being closest to OLI1. Clusters A, C and E are probably coding regions for apocytochrome b, whereas clusters B and D seem to be involved in as yet unknown functions. These conclusions rest on the following evidence. 1. Most mutants in clusters A, C and E have specifically lost cytochrome b. Many of them accumulate smaller mitochondrial translation products; some of these were identified as fragments of apocytochrome b by proteolytic fingerprinting. The molecular weight of these fragments depends on the map position of the mutant, increasing in the direction OLI2 leads to OLI1. The mutant closest to OLI1 accumulates an apocytochrome b which is slightly larger than that of wild type. 2. A mutant in cluster C exhibits a spectral absorption band of cytochrome b that is shifted 1.5 nm to the red. 3. Mutants in clusters B and D are pleiotropic. A majority of them are conditional and lack the absorption bands of both cytochrome b and cytochrome aa3; these mutants also fail to accumulate apocytochrome b and subunit I of cytochrome c oxidase and instead form a large number of abnormal translation products whose nature is unknown. 4. Zygotic complementation tests reveal at least two complementation groups: The first group includes all mutants in cluster B and the second group includes mutants in clusters (A + C + D + E).