Deletion of the Leader Peptide of the Mitochondrially Encoded Precursor of Saccharomyces Cerevisiae Cytochrome C Oxidase Subunit II

Cytochrome c oxidase subunit II (Cox2p) of Saccharomyces cerevisiae is synthesized within mitochondria as a precursor, pre-Cox2p. The 15-amino acid leader peptide is processed after export to the intermembrane space. Leader peptides are relatively unusual in mitochondrially coded proteins: indeed mammalian Cox2p lacks a leader peptide. We generated two deletions in the S. cerevisiae COX2 gene, removing either the leader peptide (cox2-20) or the leader peptide and processing site (cox2-21) without altering either the promoter or the mRNA-specific translational activation site. When inserted into mtDNA, both deletions substantially reduced the steady-state levels of Cox2p and caused a tight nonrespiratory phenotype. A respiring pseudorevertant of the cox2-20 mutant was heteroplasmic for the original mutant mtDNA and a ρ(-) mtDNA whose deletion fused the first 251 codons of the mitochondrial gene encoding cytochrome b to the cox2-20 sequence. The resulting fusion protein was processed to yield functional Cox2p. Thus, the presence of amino-terminal cytochrome b sequence bypassed the need for the pre-Cox2p leader peptide. We propose that the pre-Cox2p leader peptide contains a targeting signal necessary for membrane insertion, without which it remains in the matrix and is rapidly degraded.     

Functional expression of human mitochondrial CYP11B2 in fission yeast and identification of a new internal electron transfer protein, etp1

Mitochondrial cytochrome P450 enzymes play a crucial role in the steroid biosynthesis in human adrenals, catalyzing regio- and stereospecific hydroxylations. In search of a new model system for the study of these enzymes, we expressed the human CYP11B2 (aldosterone synthase, P450(aldo)) in fission yeast Schizosaccharomyces pombe. Analysis of the subcellular localization of the P450 enzyme by Western blot analysis, fluorescence microscopy, and electron microscopy demonstrated that the mitochondrial localization signal of the human protein is functional in S. pombe. The transformed yeasts show the inducible ability to convert in vivo considerable amounts of 11-deoxycortisol to cortisol and 11-deoxycorticosterone to corticosterone, 18-hydroxycorticosterone, and aldosterone, respectively. Although in mammalian cells, mitochondrial steroid hydroxylases depend for their activity on an electron transport chain that consists of two proteins, adrenodoxin and adrenodoxin reductase, no coexpression of these proteins is needed for efficient substrate conversion by intact fission yeast cells. Searching the fission yeast genome for adrenodoxin homologues, a gene was identified that codes for a protein with an amino terminal domain homologous to COX15 of Saccharomyces cerevisiae and a carboxy terminal ferredoxin domain. It was found that overexpression of this gene significantly enhances steroid hydroxylase activity of CYP11B2 expressing fission yeast cells. Moreover, the bacterially expressed ferredoxin domain of this protein can replace adrenodoxin in a reconstituted steroid hydroxylation assay and transfer electrons from adrenodoxin reductase to a mammalian or a bacterial cytochrome P450. Therefore, we suggest to name this protein etp1 (electron-transfer protein 1).     

In Vivo Analysis of Saccharomyces Cerevisiae Cox2 mRNA 5''-Untranslated Leader Functions in Mitochondrial Translation Initiation and Translational Activation

We have used mutational and revertant analysis to study the elements of the 54-nucleotide COX2 5'-untranslated leader involved in translation initiation in yeast mitochondria and in activation by the COX2 translational activator, Pet111p. We generated a collection of mutants with substitutions spanning the entire COX2 5'-UTL by in vitro mutagenesis followed by mitochondrial transformation and gene replacement. The phenotypes of these mutants delimit a 31-nucleotide segment, from -16 to -46, that contains several short sequence elements necessary for COX2 5'-UTL function in translation. The sequences from -16 to -47 were shown to be partially sufficient to promote translation in a foreign context. Analysis of revertants of both the series of linker-scanning alleles and two short deletion/insertion alleles has refined the positions of several possible functional elements of the COX2 5'-untranslated leader, including a putative RNA stem-loop structure that functionally interacts with Pet111p and an octanucleotide sequence present in all S. cerevisiae mitochondrial mRNA 5'-UTLs that is a potential rRNA binding site.     

Antagonistic signals within the COX2 mRNA coding sequence control its translation in Saccharomyces cerevisiae mitochondria

Translation of the mitochondrially coded COX2 mRNA within the organelle in yeast produces the precursor of Cox2p (pre-Cox2p), which is processed and assembled into cytochrome c oxidase. The mRNA sequence of the first 14 COX2 codons, specifying the pre-Cox2p leader peptide, was previously shown to contain a positively acting element required for translation of a mitochondrial reporter gene, ARG8(m), fused to the 91st codon of COX2. Here we show that three relatively short sequences within the COX2 mRNA coding sequence, or structures they form in vivo, inhibit translation of the reporter in the absence of the positive element. One negative element was localized within codons 15 to 25 and shown to function at the level of the mRNA sequence, whereas two others are within predicted stem-loop structures formed by codons 22-44 and by codons 46-74. All three of these inhibitory elements are antagonized in a sequence-specific manner by reintroduction of the upstream positive-acting sequence. These interactions appear to be independent of 5'- and 3'-untranslated leader sequences, as they are also observed when the same reporter constructs are expressed from the COX3 locus. Overexpression of MRS2, which encodes a mitochondrial magnesium carrier, partially suppresses translational inhibition by each isolated negatively acting element, but does not suppress them in combination. We hypothesize that interplay among these signals during translation in vivo may ensure proper timing of pre-Cox2p synthesis and assembly into cytochrome c oxidase.     

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.     

Pet111p, an inner membrane-bound translational activator that limits expression of the Saccharomyces cerevisiae mitochondrial gene COX2

The protein specified by the Saccharomyces cerevisiae nuclear gene PET111 specifically activates translation of the mitochondrially coded mRNA for cytochrome c oxidase subunit II (Cox2p). We found Pet111p specifically in mitochondria of both wild-type cells and cells expressing a chromosomal gene for a functional epitope-tagged form of Pet111p. Pet111p was associated with mitochondrial membranes and was highly resistant to extraction with alkaline carbonate. Pet111p was protected from proteolytic digestion by the mitochondrial inner membrane. Thus, it is exposed only on the matrix side, where it could participate directly in organellar translation and localize Cox2p synthesis by virtue of its functional interaction with the COX2 mRNA 5'-untranslated leader. We also found that Pet111p is present at levels limiting the synthesis of Cox2p by examining the effect of altered PET111 gene dosage in the nucleus on expression of a reporter gene, cox2::ARG8(m), that was inserted into mitochondrial DNA. The level of the reporter protein, Arg8p, was one-half that of wild type in a diploid strain heterozygous for a pet111 deletion mutation, whereas it was increased 2.8-fold in a strain bearing extra copies of PET111 on a high-copy plasmid. Thus, Pet111p could play dual roles in both membrane localization and regulation of Cox2p synthesis within mitochondria.     

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.     

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.     

Isolation and characterization of COX12, the nuclear gene for a previously unrecognized subunit of Saccharomyces cerevisiae cytochrome c oxidase.

We have cloned and sequenced COX12, the nuclear gene for subunit VIb of Saccharomyces cerevisiae cytochrome c oxidase. This subunit, which was previously not found in cytochrome c oxidase purified from S. cerevisiae, has a deduced amino acid sequence which is 41% identical to the sequences of subunits VIb of bovine and human cytochrome c oxidases. The chromosomal copy of COX12 was replaced with a plasmid-derived copy of COX12, in which the coding region for the suspected cytochrome oxidase subunit was replaced with the yeast URA3 gene. The resulting Ura+ deletion strain grew poorly at room temperature and was unable to grow at 37 degrees C on ethanol/glycerol medium, whereas growth was normal at both temperatures on dextrose. This temperature-dependent, petite phenotype of the deletion strain was complemented to wild-type growth with a single copy plasmid carrying COX12. Cytochrome c oxidase activity in mitochondrial membranes from the cox12 deletion strain is decreased to 5-15% of that in membranes from the wild-type parent, and this activity is restored to normal when the cox12 deletion strain is complemented by the plasmid-borne COX12. Optical spectra of mitochondrial membranes from the cox12 deletion strain revealed that optically detectable cytochrome c oxidase is assembled at room temperature and at 37 degrees C, although the heme a + a3 absorption is diminished approximately 50%. The N-terminal amino acid sequence of the protein encoded by COX12 is identical to the N-terminal sequence of a subunit found in yeast cytochrome c oxidase purified by a new procedure (Taanman, J.-W., and Capaldi, R. A. (1992) J. Biol. Chem. 267, 22481-22485). We conclude that COX12 encodes a subunit of yeast cytochrome c oxidase which is essential during assembly for full cytochrome c oxidase activity but apparently can be removed after the oxidase is assembled, with retention of oxidase activity. This is the first instance in which deletion of a subunit of cytochrome c oxidase results in assembly of optically detectable cytochrome c oxidase but having markedly diminished activity.     

Functional analysis of the domains in Cox11

Cox11 is an intrinsic mitochondrial membrane protein essential for the assembly of an active cytochrome c oxidase complex. Cox11 is tethered to the mitochondrial inner membrane by a single transmembrane helix. Domain mapping was carried out to determine the functional segments of the Cox11 protein. The C-terminal 189 residue Cu(I)-binding domain is shown to be exposed within the mitochondrial intermembrane space. This orientation was demonstrated by the proteolytic susceptibility of a C-terminal Myc epitope tag in mitoplasts but not intact mitochondria. Fusion of the N terminus of Cox11 to the matrix ribosomal protein Rsm22 results in a functional protein capable of suppressing the respiratory defect of both Deltacox11 cells and Deltarsm22 cells. The functionality of the fusion protein suggests that the Cox11 N terminus projects into the matrix. The fusion of the C-terminal segment of Cox11 to Rsm22 resembles a naturally occurring fusion of Cox11 in Schizosaccharomyces pombe to a sequence homologous to the Saccharomyces cerevisiae Rsm22. Studies on a series of SCO1/COX11 chimeras reveal that the matrix domain of Cox11 lacks a specific function, whereas the Cu(I) binding/donating function requires the yeast Cox11 sequence. The Cu(I)-binding domain from human Cox11 cannot functionally replace the yeast sequence. The copper domain of Cox11 may be an important docking motif for Cox1 or a Cox1-associated protein.     

The ZbYME2 gene from the food spoilage yeast Zygosaccharomyces bailii confers not only YME2 functions in Saccharomyces cerevisiae, but also the capacity for catabolism of sorbate and benzoate, two major weak organic acid preservatives

A factor influencing resistances of food spoilage microbes to sorbate and benzoate is whether these organisms are able to catalyse the degradation of these preservative compounds. Several fungi metabolize benzoic acid by the beta-ketoadipate pathway, involving the hydroxylation of benzoate to 4-hydroxybenzoate. Saccharomyces cerevisiae is unable to use benzoate as a sole carbon source, apparently through the lack of benzoate-4-hydroxylase activity. However a single gene from the food spoilage yeast Zygosaccharomyces bailii, heterologously expressed in S. cerevisiae cells, can enable growth of the latter on benzoate, sorbate and phenylalanine. Although this ZbYME2 gene is essential for benzoate utilization by Z. bailii, its ZbYme2p product has little homology to other fungal benzoate-4-hydroxylases studied to date, all of which appear to be microsomal cytochrome P450s. Instead, ZbYme2p has strong similarity to the matrix domain of the S. cerevisiae mitochondrial protein Yme2p/Rna12p/Prp12p and, when expressed as a functional fusion to green fluorescent protein in S. cerevisiae growing on benzoate, is largely localized to mitochondria. The phenotypes associated with loss of the native Yme2p from S. cerevisiae, mostly apparent in yme1,yme2 cells, may relate to increased detrimental effects of endogenous oxidative stress. Heterologous expression of ZbYME2 complements these phenotypes, yet it also confers a potential for weak acid preservative catabolism that the native S. cerevisiae Yme2p is unable to provide. Benzoate utilization by S. cerevisiae expressing ZbYME2 requires a functional mitochondrial respiratory chain, but not the native Yme1p and Yme2p of the mitochondrion.     

Cytochrome oxidase assembly in yeast requires the product of COX11, a homolog of the P. denitrificans protein encoded by ORF3.

The synthesis of cytochrome oxidase in Saccharomyces cerevisiae was recently shown to require a protein encoded by the nuclear gene COX10. This protein was found to be homologous to the putative protein product of the open reading frame ORF1 reported in one of the cytochrome oxidase operons of Paracoccus denitrificans. In the present study we demonstrate the existence in yeast of a second nuclear gene, COX11, whose encoded protein is homologous to another open reading frame (ORF3) present in the same operon of P. denitrificans. Mutations in COX11 elicit a deficiency in cytochrome oxidase. In this and in other respects cox11 and cox10 mutants have very similar phenotypes. An antibody has been obtained against the yeast COX11 protein. The antibody recognizes a 28 kd protein in yeast mitochondria, consistent with the size of the protein predicted from the sequence of COX11. The COX11 protein is tightly associated with the mitochondrial membrane but is not a component of purified cytochrome oxidase. An analysis of cytochrome oxidase subunits in wild type and in a cox11 mutant suggests that the COX11 protein is not required either for synthesis or transport of the subunit polypeptides into mitochondria. It seems more probable that COX11 protein exerts its effect at some terminal stage of enzyme synthesis, perhaps in directing assembly of the subunits.     

Functional analysis of mitochondrial protein import in yeast

In order to facilitate studies on protein localization to and sorting within yeast mitochondria, we have designed an experimental system that utilizes a new vector and a functional assay. The vector, which we call an LPS plasmid (for leader peptide substitution), employs a yeast COX5a gene (the structural gene for subunit Va of the inner membrane protein complex cytochrome c oxidase) as a convenient reporter for correct mitochondrial localization. Using in vitro mutagenesis, we have modified COX5a so that the DNA sequences encoding the wild-type subunit Va leader peptide can be precisely deleted and replaced with a given test sequence. The substituted leader peptide can then be analyzed for its ability to direct subunit Va to the inner mitochondrial membrane (to target and sort) by complementation or other in vivo assays. In this study we have tested the ability of several heterologous sequences to function in this system. The results of these experiments indicate that a functional leader peptide is required to target subunit Va to mitochondria. In addition, leader peptides, or portions thereof, derived from proteins located in other mitochondrial compartments can also be used to properly localize this polypeptide. The results presented here also indicate that the information necessary to sort subunit Va to the inner mitochondrial membrane does not reside in the leader peptide but rather in the mature subunit Va sequence.