Sequences required for delivery and localization of the ADP/ATP translocator to the mitochondrial inner membrane.

The ADP/ATP translocator, a transmembrane protein of the mitochondrial inner membrane, is coded in Saccharomyces cerevisiae by the nuclear gene PET9. DNA sequence analysis of the PET9 gene showed that it encoded a protein of 309 amino acids which exhibited a high degree of homology with mitochondrial translocator proteins from other sources. This mitochondrial precursor, in contrast to many others, does not contain a transient presequence which has been shown to direct the posttranslational localization of proteins in the organelle. Gene fusions between the PET9 gene and the gene encoding beta-galactosidase (lacZ) were constructed to define the location of sequences necessary for the mitochondrial delivery of the ADP/ATP translocator protein in vivo. These studies reveal that the information to target the hybrid molecule to the mitochondria is present within the first 115 residues of the protein. In addition, these studies suggest that the "import information" of the amino-terminal region of the ADP/ATP translocator precursor is twofold. In addition to providing targeting function of the precursor to the organelle, these amino-terminal sequences act to prevent membrane-anchoring sequences located between residues 78 and 98 from stopping import at the outer mitochondrial membrane. These results are discussed in light of the function of distinct protein elements at the amino terminus of mitochondrially destined precursors in both organelle delivery and correct membrane localization.     

Nuclear genes coding the yeast mitochondrial adenosine triphosphatase complex. Primary sequence analysis of ATP2 encoding the F1-ATPase beta-subunit precursor

The yeast nuclear gene ATP2 encodes a F1-ATPase beta-subunit protein of 509 amino acids with a predicted mass of 54,575 daltons. In contrast to the ATPase beta-subunit proteins determined previously from Escherichia coli and various plant sources, the yeast mitochondrial precursor peptide contains a unique cysteine residue within its immediate amino terminus. Expression of an in-frame deletion in ATP2 between residues 28 and 34 to eliminate this single cysteine residue located near the processing site of the matrix protease does not prevent the in vivo delivery of the subunit to mitochondria or its assembly into a functional ATPase complex. Thus, the import F1 beta-subunit into mitochondria does not require a covalent modification of the type utilized for the secretion of the major lipoprotein from E. coli. In addition, analysis of the level of the major F1-ATPase subunits in mitochondria prepared from an atp2- disruption mutant demonstrates that the in vivo import of these catalytic subunits is not dependent on each other. These data and additional studies, therefore, suggest that the determinants for mitochondrial delivery reside within the amino terminus of the individual precursors.     

mRNA localization to the mitochondrial surface allows the efficient translocation inside the organelle of a nuclear recoded ATP6 protein

As previously established in yeast, two sequences within mRNAs are responsible for their specific localization to the mitochondrial surface-the region coding for the mitochondrial targeting sequence and the 3'UTR. This phenomenon is conserved in human cells. Therefore, we decided to use mRNA localization as a tool to address to mitochondria, a protein that is not normally imported. For this purpose, we associated a nuclear recoded ATP6 gene with the mitochondrial targeting sequence and the 3'UTR of the nuclear SOD2 gene, which mRNA exclusively localizes to the mitochondrial surface in HeLa cells. The ATP6 gene is naturally located into the organelle and encodes a highly hydrophobic protein of the respiratory chain complex V. In this study, we demonstrated that hybrid ATP6 mRNAs, as the endogenous SOD2 mRNA, localize to the mitochondrial surface in human cells. Remarkably, fusion proteins localize to mitochondria in vivo. Indeed, ATP6 precursors synthesized in the cytoplasm were imported into mitochondria in a highly efficient way, especially when both the MTS and the 3'UTR of the SOD2 gene were associated with the re-engineered ATP6 gene. Hence, these data indicate that mRNA targeting to the mitochondrial surface represents an attractive strategy for allowing the mitochondrial import of proteins originally encoded by the mitochondrial genome without any amino acid change in the protein that could interfere with its biologic activity.     

Isolation of the ATP synthase subunit 6 and sequence of the mitochondrial ATP6 gene of the yeast Candida parapsilosis.

The mitochondrially translated product called subunit 6 was extracted from the yeast Candida parapsilosis mitochondria using an organic solvent mixture and purified by reverse-phase HPLC. The partial N-terminal sequence of subunit 6 reveals a post-translational cleavage site as in Saccharomyces cerevisiae. The structural mitochondrial gene ATP6 was isolated form a mitochondrial DNA library using the oligonucleotide probe procedure. The gene and the surrounding regions were cloned into M13tg130 and M13tg131 phage vectors. The insert contained an open reading frame 738-bp encoding a 246-amino-acid polypeptide. Mature subunit 6 contains 243 amino acid residues and the predicted molecular mass is 26,511 Da. The subunit shows 52% similarity with ATP synthase subunit 6 of the yeast S. cerevisiae. Comparison between protein and DNA sequences shows that the CUN codon family codes for a leucine in C. parapsilosis mitochondria.     

Transport of the yeast ATP synthase beta-subunit into mitochondria. Effects of amino acid substitutions on targeting.

We have isolated the yeast ATP2 gene encoding the beta-subunit of mitochondrial ATP synthase and determined its nucleotide sequence. A fusion between the N-terminal 15 amino acid residues of beta-subunit and the mouse cytosolic protein dihydrofolate reductase (DHFR) was transcribed and translated in vitro and found to be transported into isolated yeast mitochondria. A fusion with the first 35 amino acid residues of beta-subunit attached to DHFR was not only transported but also proteolytically processed by a mitochondrial protease. Amino acid substitutions were introduced into the N-terminal presequence of the beta-subunit by bisulphite mutagenesis of the corresponding DNA. The effects of these mutations on mitochondrial targeting were assessed by transport experiments in vitro using DHFR fusion proteins. All of the mutants, harbourin from one to six amino acid substitutions in the first 14 residues of the presequence, were transported into mitochondria, though at least one of them (I8) was transported and proteolytically processed at a much reduced rate. The I8 mutant beta-subunit also exhibited poor transport and processing in vivo, and expression of this mutant polypeptide failed to complement the glycerol- phenotype of a yeast ATP2 mutant. More remarkably, the expression of I8 beta-subunit induced a more general growth defect in yeast, possibly due to interference with the transport of other, essential, mitochondrial proteins.     

Targeting efficiency of a mitochondrial pre-sequence is dependent on the passenger protein.

The mitochondrial matrix enzyme manganese superoxide dismutase (SOD) of Saccharomyces cerevisiae is encoded in the nucleus. It is synthesized as a precursor with an NH2-terminal extension of 26 amino acids which is cleaved off during import into the mitochondrion. Fusions between the NH2-terminal 34 amino acids of SOD and the cytosolic proteins invertase of yeast and mouse dihydrofolate reductase (DHFR) were tested for in vitro binding and import into mitochondria. Efficient translocation over the mitochondrial membranes takes place in the case of the SOD-DHFR fusion. The SOD-invertase fusion protein does not get translocated and binds to the organelle with only low efficiency. Yeast transformants harbouring the SOD-invertase fusion gene accumulate approximately 95% of the hybrid protein in the cytosol. The remaining material is found in the interior of the mitochondrion, loosely attached to the inner membrane. We conclude that the pre-sequence of SOD is able to deliver a passenger protein to the mitochondrion. The efficiency of protein delivery and translocation across the membrane is, however, influenced by the passenger protein.     

The mitochondrial F1ATPase alpha-subunit is necessary for efficient import of mitochondrial precursors.

The mitochondrial import and assembly of the F1ATPase subunits requires, respectively, the participation of the molecular chaperones hsp70SSA1 and hsp70SSC1 and other components operating on opposite sides of the mitochondrial membrane. In previous studies, both the homology and the assembly properties of the F1ATPase alpha-subunit (ATP1p) compared to the groEL homologue, hsp60, have led to the proposal that this subunit could exhibit chaperone-like activity. In this report the extent to which this subunit participates in protein transport has been determined by comparing import into mitochondria that lack the F1ATPase alpha-subunit (delta ATP1) versus mitochondria that lack the other major catalytic subunit, the F1ATPase beta-subunit (delta ATP2). Yeast mutants lacking the alpha-subunit but not the beta-subunit grow much more slowly than expected on fermentable carbon sources and exhibit delayed kinetics of protein import for several mitochondrial precursors such as the F1 beta subunit, hsp60MIF4 and subunits 4 and 5 of the cytochrome oxidase. In vitro and in vivo the F1 beta-subunit precursor accumulates as a translocation intermediate in absence of the F1 alpha-subunit. In the absence of both the ATPase subunits yeast grows at the same rate as a strain lacking only the beta-subunit, and import of mitochondrial precursors is restored to that of wild type. These data indicate that the F1 alpha-subunit likely functions as an "assembly partner" to influence protein import rather than functioning directly as a chaperone. These data are discussed in light of the relationship between the import and assembly of proteins in mitochondria.     

The N-terminal extension of the ADP/ATP translocator is not involved in targeting to plant mitochondria in vivo

The mitochondrial ADP/ATP translocator, also called adenine nucleotide translocase (ANT), is synthesized in plants with an N-terminal extension which is cleaved upon import into mitochondria. In contrast, the homologous proteins of mammals or fungi do not contain such a transient amino terminal presequence. To investigate whether the N-terminal extension is needed for correct intracellular sorting in vivo , translational fusions were constructed of the translocator cDNA—with and without presequence—with the β-glucuronidase ( gus ) reporter gene. The distribution of reporter enzymatic activity in the subcellular compartments of transgenic plants and transformed yeast cells was subsequently analysed. The results show that: (i) the plant translocator presequence is not necessary for the correct localization of the ANT to the mitochondria; (ii) the mitochondrial targeting information contained in the mature part of the protein is sufficient to overcome, to some extent, the presence of plastid transit peptides; and (iii) the presequence alone is not able to target a passenger protein to mitochondria in vivo .     

Atp11p and Atp12p are chaperones for F(1)-ATPase biogenesis in mitochondria

The bioenergetic needs of aerobic cells are met principally through the action of the F(1)F(0) ATP synthase, which catalyzes ATP synthesis during oxidative phosphorylation. The catalytic unit of the enzyme (F(1)) is a multimeric protein of the subunit composition alpha(3)beta(3)(gamma)(delta) epsilon. Our work, which employs the yeast Saccharomyces cerevisiae as a model system for studies of mitochondrial function, has provided evidence that assembly of the mitochondrial alpha and beta subunits into the F(1) oligomer requires two molecular chaperone proteins called Atp11p and Atp12p. Comprehensive knowledge of Atp11p and Atp12p activities in mitochondria bears relevance to human physiology and disease as these chaperone actions are now known to exist in mitochondria of human cells.     

Sequences distal to the mitochondrial targeting sequences are necessary for the maturation of the F1-ATPase beta-subunit precursor in mitochondria

The beta-subunit of the mitochondrial F1-ATPase is synthesized as a precursor in the cytoplasm which is delivered through two bilayers bounding the mitochondria prior to its assembly with other proteins into a functional complex. In order to determine the role of the amino-terminal 50 residues of the precursor on its localization, maturation, and assembly, a set of deletions within this region of the ATP2 gene encoding the beta-subunit has been analyzed. These studies reveal that deletions between residue 10 of the F1 beta-presequence and residue 36 can still direct in vivo mitochondrial import and assembly of the mutant subunit into a functional complex. Deletions within ATP2 which contain less than the first 10 residues of the precursor are not imported. Thus, the extreme amino terminus (about half of the transient presequence) of the F1 beta-subunit can direct its mitochondrial import. The wild-type F1 beta-subunit precursor is matured by the matrix-located metalloprotease at Lys19-Gln20; however, small in-frame deletions up to 17 residues distal to this site fail to be matured either in vitro or in vivo. This nonmatured F1 beta-subunit is also assembled into a functional enzyme and supports growth of its host on a nonfermentable carbon source. These data indicate that maturation of the F1 beta-subunit precursor is dependent on a protein sequence located distal to the proteolytic maturation site which is distinct from the mitochondrial targeting sequence.     

Expression and function of heterologous forms of malate dehydrogenase in yeast.

The structure of the tricarboxylic acid cycle enzyme malate dehydrogenase is highly conserved in various organisms. To test the extent of functional conservation, the rat mitochondrial enzyme and the enzyme from Escherichia coli were expressed in a strain of Saccharomyces cerevisiae containing a disruption of the chromosomal MDH1 gene encoding yeast mitochondrial malate dehydrogenase. The authentic precursor form of the rat enzyme, expressed using a yeast promoter and a multicopy plasmid, was found to be efficiently targeted to yeast mitochondria and processed to a mature active form in vivo. Mitochondrial levels of the polypeptide and malate dehydrogenase activity were found to be similar to those for MDH1 in wild-type yeast cells. Efficient expression of the E. coli mdh gene was obtained with multicopy plasmids carrying gene fusions encoding either a mature form of the procaryotic enzyme or a precursor form with the amino terminal mitochondrial targeting sequence from yeast MDH1. Very low levels of mitochondrial import and processing of the precursor form were obtained in vivo and activity could be demonstrated for only the expressed precursor fusion protein. Results of in vitro import experiments suggest that the percursor form of the E. coli protein associates with yeast mitochondria but is not efficiently internalized. Respiratory rates measured for isolated yeast mitochondria containing the mammalian or procaryotic enzyme were, respectively, 83 and 62% of normal, suggesting efficient delivery of NADH to the respiratory chain. However, expression of the heterologous enzymes did not result in full complementation of growth phenotypes associated with disruption of the yeast MDH1 gene.     

A yeast model of the neurogenic ataxia retinitis pigmentosa (NARP) T8993G mutation in the mitochondrial ATP synthase-6 gene

NARP (neuropathy, ataxia, and retinitis pigmentosa) and MILS (maternally inherited Leigh syndrome) are mitochondrial disorders associated with point mutations of the mitochondrial DNA (mtDNA) in the gene encoding the Atp6p subunit of the ATP synthase. The most common and studied of these mutations is T8993G converting the highly conserved leucine 156 into arginine. We have introduced this mutation at the corresponding position (183) of yeast Saccharomyces cerevisiae mitochondrially encoded Atp6p. The "yeast NARP mutant" grew very slowly on respiratory substrates, possibly because mitochondrial ATP synthesis was only 10% of the wild type level. The mutated ATP synthase was found to be correctly assembled and present at nearly normal levels (80% of the wild type). Contrary to what has been reported for human NARP cells, the reverse functioning of the ATP synthase, i.e. ATP hydrolysis in the F(1) coupled to F(0)-mediated proton translocation out of the mitochondrial matrix, was significantly compromised in the yeast NARP mutant. Interestingly, the oxygen consumption rate in the yeast NARP mutant was decreased by about 80% compared with the wild type, due to a selective lowering in cytochrome c oxidase (complex IV) content. This finding suggests a possible regulatory mechanism between ATP synthase activity and complex IV expression in yeast mitochondria. The availability of a yeast NARP model could ease the search for rescuing mechanisms against this mitochondrial disease.     

Functional expression of hexahistidine-tagged beta-subunit of yeast F1-ATPase and isolation of the enzyme by immobilized metal affinity chromatography

Mitochondrial ATP synthase (F1Fo-ATPase) catalyzes the terminal step of oxidative phosphorylation. In this paper, we demonstrate the functional expression of the hexahistidine-tagged beta-subunit of yeast ATP synthase and the purification of the F1-ATPase from yeast cells. A gene encoding the beta-subunit from Saccharomyces cerevisiae was modified to encode a protein of which the original N-terminus import signal sequence was replaced by a sequence containing the import signal sequence of a mitochondrial ATPase inhibitor, its processing site, and six consecutive histidines. Expression of the modified gene generated a functional F1Fo complex in host yeast cells lacking a functional copy of the endogenous ATP2 gene, as judged by growth of rescued cells on lactate medium. F1 was extracted from the yeast mitochondria by chloroform treatment and purified by immobilized metal affinity chromatography and gel filtration chromatography. The specific activity of the purified F1 was comparable to that of the wild-type enzyme, and the F1 contained all of the 5 known subunits (alpha, beta, gamma, delta, and epsilon). Moreover, the activity of the F1 was completely inhibited by the specific ATPase inhibitor protein, IF1. These results indicate that F1 containing the tagged beta-subunit is fully assembled and active. The application of this novel procedure simplifies the number of steps required for the isolation of F1 used for studying the molecular mechanism of catalysis and regulation of the enzyme.     

Yeast mitochondrial biogenesis: a model system for humans?

Recently, our knowledge of yeast mitochondrial biogenesis has considerably progressed. This concerns the import machinery that guides preproteins synthesized on the cytoplasmic ribosomes through the mitochondrial outer and inner membranes, as well as the inner membrane insertion machinery of mitochondrially encoded polypeptides, or the proteins participating in the assembly and quality control of the respiratory complexes and ATP synthase. More recently, two new fields have emerged, biosynthesis of the iron-sulfur clusters and dynamics of the mitochondrion. Many of the newly discovered yeast proteins have homologues in human mitochondria. Thus, Saccharomyces cerevisiae has proven a particularly suitable simple organism for approaching the molecular bases of a growing number of human mitochondrial diseases caused by mutations in nuclear genes identified by positional cloning.     

A yeast mitochondrial presequence functions as a signal for targeting to plant mitochondria in vivo.

To date, the presequence of the mitochondrial beta-subunit of ATPase from tobacco is the only signal sequence that has been shown to target a foreign protein into plant mitochondria in vivo. Here we report that the presequence of a yeast mitochondrial protein directs bacterial beta-glucuronidase (GUS) specifically into the mitochondrial compartment of transgenic tobacco plants. Fusions between the presequence of the mitochondrial tryptophanyl-tRNA-synthetase gene from yeast and the GUS gene have been introduced into tobacco plants and yeast cells. In both systems, proteins containing the complete yeast mitochondrial presequence are efficiently imported in the mitochondria. Measurements of GUS activity in different subcellular fractions indicate that there is no substantial misrouting of the chimeric proteins in plant cells. In vitro synthesized GUS fusion proteins have a higher molecular weight than those found inside yeast and tobacco mitochondria, suggesting a processing of the precursors during import. Interestingly, fusion proteins translocated across the mitochondrial membranes of tobacco have the same size as those that are imported into yeast mitochondria. We conclude that the processing enzyme in plant mitochondria may recognize a proximate or even the same cleavage site within the mitochondrial tryptophanyl-tRNA-synthetase presequence as the matrix protease from yeast.     

The role of protein structure in the mitochondrial import pathway. Unfolding of mitochondrially bound precursors is required for membrane translocation

In order to examine the influence of protein structure on the post-translational import of a protein into mitochondria, the carboxyl-terminal 129 residues of F1-ATPase beta-subunit precursor (511aa) have been replaced with 61 residues of yeast copper metallothionein. Import of the F1 beta-copper metallothionein (beta CuMT) hybrid into mitochondria was as efficient as that of the F1 beta precursor in the absence of copper. Addition of copper to mitochondrial import reactions, which had no significant effect on import of the F1 beta-subunit precursor, blocked import of the beta CuMT protein. This copper-dependent transport block for the beta CuMT precursor occurred after the precursor was bound to mitochondria. Expression of the beta CuMT protein in vivo revealed that beta CuMT would bind copper and allow growth of a copper-sensitive yeast host on an otherwise inhibitory level of the cation as long as it was localized in the cytoplasm. These data indicate that the binding of copper by beta CuMT renders it refractile for partial unfolding which is necessary for its translocation into mitochondria. These observations provide an alternative scheme for the selection of mutants defective in mitochondrial import.     

ATP25, a new nuclear gene of Saccharomyces cerevisiae required for expression and assembly of the Atp9p subunit of mitochondrial ATPase

We report a new nuclear gene, designated ATP25 (reading frame YMR098C on chromosome XIII), required for expression of Atp9p (subunit 9) of the Saccharomyces cerevisiae mitochondrial proton translocating ATPase. Mutations in ATP25 elicit a deficit of ATP9 mRNA and of its translation product, thereby preventing assembly of functional F(0). Unlike Atp9p, the other mitochondrial gene products, including ATPase subunits Atp6p and Atp8p, are synthesized normally in atp25 mutants. Northern analysis of mitochondrial RNAs in an atp25 temperature-sensitive mutant confirmed that Atp25p is required for stability of the ATP9 mRNA. Atp25p is a mitochondrial inner membrane protein with a predicted mass of 70 kDa. The primary translation product of ATP25 is cleaved in vivo after residue 292 to yield a 35-kDa C-terminal polypeptide. The C-terminal half of Atp25p is sufficient to stabilize the ATP9 mRNA and restore synthesis of Atp9p. Growth on respiratory substrates, however, depends on both halves of Atp25p, indicating that the N-terminal half has another function, which we propose to be oligomerization of Atp9p into a proper size ring structure.     

The assembly factor Atp11p binds to the beta-subunit of the mitochondrial F(1)-ATPase

Atp11p is a protein of Saccharomyces cerevisiae required for the assembly of the F(1) component of the mitochondrial F(1)F(0)-ATP synthase. This study presents evidence that Atp11p binds selectively to the beta-subunit of F(1). Under conditions in which avidin-Sepharose beads specifically adsorbed biotinylated Atp11p from yeast mitochondrial extracts, the F(1) beta-subunit coprecipitated with the tagged Atp11p protein. Binding interactions between Atp11p and the entire beta-subunit of F(1) or fragments of the beta-subunit were also revealed by a yeast two-hybrid screen: Atp11p bound to a region of the nucleotide-binding domain of the beta-subunit located between Gly(114) and Leu(318). Certain elements of this sequence that would be accessible to Atp11p in the free beta-subunit make contact with adjacent alpha-subunits in the assembled enzyme. This observation suggests that the alpha-subunits may exchange for bound Atp11p during the process of F(1) assembly.     

Studies on the import into mitochondria of yeast ATP synthase subunits 8 and 9 encoded by artificial nuclear genes

Direct fusions have been constructed between each of subunits 8 and 9 from mitochondrial ATPase of Saccharomyces cerevisiae, proteins normally encoded inside mitochondria, and the cleavable N-terminal transit peptide from the nuclearly encoded precursor to subunit 9 of Neurospora crassa mitochondrial ATPase. The subunit 8 construct was imported efficiently into isolated yeast mitochondria and was processed at or very near the fusion point. When expressed in vivo from its artificial nuclear gene, this cytoplasmically synthesized form of subunit 8 restored the growth defects of aap 1 mutants unable to produce subunit 8 inside the mitochondria. The subunit 9 construct was, however, unable to be imported into isolated mitochondria and could not, following nuclear expression in vivo, complement growth defects in mitochondrial oli 1 mutants. This behaviour is contrasted with the previously demonstrated import competence of another yeast subunit 9 fusion, bearing the first five residues of mature N. crassa subunit 9 interposed between its own transit peptide and the yeast subunit 9 moiety.     

ADP-ATP carrier of Saccharomyces cerevisiae contains a mitochondrial import signal between amino acids 72 and 111

The ADP-ATP carrier (also referred to as the adenine nucleotide translocator) of Saccharomyces cerevisiae is encoded by a nuclear gene, translated in the cytosol, and imported into the mitochondrial inner membrane. In order to study the determinants of mitochondrial import, a series of fusion proteins, consisting of the first 21, 72, and 111 amino acids of the ADP-ATP carrier, joined to mouse dihydrofolate reductase were generated. Dihydrofate reductase is a cytoslic protein that does not bind mitochondria. The reticulocyte lysate reaction containing the 35S-methionine-labeled protein was incubated with mitochondria in a buffer containing 3% BSA. Following incubation for import, the reactions were treated with 1 mM PMSF or 25 micrograms/ml proteinase K; mitochondria were reisolated and analyzed by gel electrophoresis. The 21 and 72 amino acid hybrid proteins showed a low level of binding to mitochondria: the bound form was entirely protease accessible. The 111 amino acid hybrid protein was imported to a protease-protected location within mitochondria. It is concluded that the first 72 amino acids of the ADP-ATP carrier do not suffice to import the protein into mitochondria and that the region between amino acids 72 and 111, a region that contains a transmembrane-spanning domain, constitutes at least part of the mitochondrial import signal.