The adenine nucleotide translocator of higher plants is synthesized as a large precursor that is processed upon import into mitochondria.

Two maize genes and cDNAs encoding the mitochondrial adenine nucleotide translocator (ANT), a nuclear-encoded inner mitochondrial membrane carrier protein, have previously been isolated in this laboratory. Sequence analysis revealed the existence of much longer open reading frames than the corresponding fungal and mammalian ANT genes. Potato ANT cDNAs have subsequently been isolated and sequenced and alignment of the deduced plant amino acid sequences with the equivalent fungal and mammalian polypeptides indicated that the plant proteins contain N-terminal extensions. When the plant cDNA clones are expressed in vitro they direct the synthesis of precursor proteins that are specifically processed at the N-terminus upon import into isolated mitochondria. N-terminal amino acid sequence data obtained from the native proteins purified from both maize and potato mitochondria has allowed identification of the putative processing sites. Further import analysis has shown that two distinct regions of the maize precursor protein contain targeting information, the 97 amino acids at the N-terminus and the 267 C-terminal amino acids. This is the first report that provides experimental evidence that the adenine nucleotide translocator of higher plants is synthesized as a large precursor protein that is specifically cleaved upon import into mitochondria. Import of ANT into higher plant mitochondria therefore appears to be different to the corresponding process in fungal and mammalian systems where targeting of ANT to mitochondria is mediated by internal signals and there is no N-terminal processing.     

The N-terminal cleavable extension of plant carrier proteins is responsible for efficient insertion into the inner mitochondrial membrane

A subset of mitochondrial carrier proteins from plants contain a cleavable N-terminal extension. We have used a reconstituted protein import assay system into intermembrane space-depleted mitochondria to study the role of the cleavable extension in the carrier import pathway. Insertion of carrier proteins into the inner membrane can be stimulated by the addition of a soluble intermembrane space fraction isolated from plant mitochondria. Greater stimulation of import of the adenine nucleotide carrier (ANT) and phosphate carrier (Pic), which contain N-terminal cleavable extensions, was observed compared to the import of the oxoglutarate malate carrier (OMT), which does not contain a cleavable extension. Removal of the N-terminal cleavable extension from ANT and Pic resulted in loss of stimulation of insertion into the inner membrane. Conversely, addition of the N-terminal extension from ANT or Pic to OMT resulted in significantly enhanced insertion into the inner membrane. The polytopic inner membrane proteins TIM17 and TIM23 that are imported via the carrier import pathway contain no cleavable extension, displayed high-level stimulation of insertion into the inner membrane by addition of the intermembrane space fraction. Addition of the N-terminal cleavable extension from carrier proteins to TIM23 enhanced insertion of TIM23 into the inner membrane even in the absence of the soluble intermembrane space fraction. Together, these results demonstrate that the cleavable N-terminal extensions present on carrier proteins from plants are required for efficient insertion into the inner mitochondrial membrane, and that they can stimulate insertion of any carrier-like protein into the inner membrane.     

Characterization of Arabidopsis enhanced disease susceptibility mutants that are affected in systemically induced resistance

The evolutionarily recent transfer of the gene for cytochrome c oxidase subunit 2 (cox2) from the mitochondrion to the nucleus in legumes is shown to have involved novel gene-activation steps. The acquired mitochondrial targeting presequence is bordered by two introns. Characterization of the import of soybean Cox2 indicates that the presequence is cleaved in a three-step process which is independent of assembly. The final processing step takes place only in the mitochondria of legume species, and not in several non-legume plants. The unusually long presequence of 136 amino acids consists of three regions: the first 20 amino acids are required for mitochondrial targeting and can be replaced by another presequence; the central portion of the presequence is required for efficient import of the Cox2 protein into mitochondria; and the last 12 amino acids, derived from the mitochondrially encoded protein, are required for correct maturation of the imported protein. The acquisition of a unique presequence, and the capacity for legume mitochondria to remove this presequence post-import, are considered to be essential adaptations for targeting of Cox2 to the mitochondrion and therefore activation of the transferred gene in the nucleus.     

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.     

NMR identification of the Tom20 binding segment in mitochondrial presequences

Many mitochondrial proteins are synthesized in the cytosol as precursors with N-terminal presequences, and are imported into mitochondria with the aid of translocator protein complexes containing presequence-binding proteins. Tom20, a receptor protein which functions in an early step of the mitochondrial protein import, recognizes presequences with divergent amino acid sequences. Here, we report the identification of the segments involved in binding to Tom20 in mitochondrial presequences. We monitored the chemical shift perturbation of the NMR signals of five different 15N-labeled presequence peptides by the addition of the cytosolic receptor domain of rat or yeast Tom20. The perturbed segments occupy different positions, either near the N terminus or at the C terminus, in the presequences. Spin label experiments revealed that this is not due to different orientations of the presequence peptides bound to Tom20. The results presented here will offer a starting point to perform detailed analyses of Tom20-binding elements by systematic amino acid replacements.     

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.     

Functions of outer membrane receptors in mitochondrial protein import

Most mitochondrial proteins are synthesized in the cytosol as precursor proteins and are imported into mitochondria. The targeting signals for mitochondria are encoded in the presequences or in the mature parts of the precursor proteins, and are decoded by the receptor sites in the translocator complex in the mitochondrial outer membrane. The recently determined NMR structure of the general import receptor Tom20 in a complex with a presequence peptide reveals that, although the amphiphilicity and positive charges of the presequence is essential for the import ability of the presequence, Tom20 recognizes only the amphiphilicity, but not the positive charges. This leads to a new model that different features associated with the mitochondrial targeting sequence of the precursor protein can be recognized by the mitochondrial protein import system in different steps during the import.     

Mitochondrial protein import. Requirement of presequence elements and tom components for precursor binding to the TOM complex

Protein translocation across the outer mitochondrial membrane is mediated by the translocator called the TOM (translocase of the outer mitochondrial membrane) complex. The TOM complex possesses two presequence binding sites on the cytosolic side (the cis site) and on the intermembrane space side (the trans site). Here we analyzed the requirement of presequence elements and subunits of the TOM complex for presequence binding to the cis and trans sites of the TOM complex. The N-terminal 14 residues of the presequence of subunit 9 of F(0)-ATPase are required for binding to the trans site. The interaction between the presequence and the cis site is not sufficient to anchor the precursor protein to the TOM complex. Tom7 constitutes or is close to the trans site and has overlapping functions with the C-terminal intermembrane space domain of Tom22 in the mitochondrial protein import.     

The fourth isoform of the adenine nucleotide translocator inhibits mitochondrial apoptosis in cancer cells

The adenine nucleotide translocator (ANT) is a mitochondrial bi-functional protein, which catalyzes the exchange of ADP and ATP between cytosol and mitochondria and participates in many models of mitochondrial apoptosis. The human adenine nucleotide translocator sub-family is composed of four isoforms, namely ANT1–4, encoded by four nuclear genes, whose expression is highly regulated. Previous studies have revealed that ANT1 and 3 induce mitochondrial apoptosis, whereas ANT2 is anti-apoptotic. However, the role of the recently identified isoform ANT4 in the apoptotic pathway has not yet been elucidated. Here, we investigated the effects of stable heterologous expression of the ANT4 on proliferation, mitochondrial respiration and cell death in human cancer cells, using ANT3 as a control of pro-apoptotic isoform. As expected, ANT3 enhanced mitochondria-mediated apoptosis in response to lonidamine, a mitochondriotoxic chemotherapeutic drug, and staurosporine, a protein kinase inhibitor. Our results also indicate that the pro-apoptotic effect of ANT3 was accompanied by decreased rate of cell proliferation, alteration in the mitochondrial network topology, and decreased reactive oxygen species production. Of note, we demonstrate for the first time that ANT4 enhanced cell growth without impacting mitochondrial network or respiration. Moreover, ANT4 differentially regulated the intracellular levels of hydrogen peroxide without affecting superoxide anion levels. Finally, stable ANT4 overexpression protected cancer cells from lonidamine and staurosporine apoptosis in a manner independent of Bcl-2 expression. These data highlight a hitherto undefined cytoprotective activity of ANT4, and provide a novel dichotomy in the human ANT isoform sub-family with ANT1 and 3 isoforms functioning as pro-apoptotic while ANT2 and 4 isoforms render cells resistant to death inducing stimuli.     

Nucleotide sequence of cDNA clones encoding the β subunit of mitochondrial ATP synthase from the green alga Chlamydomonas reinhardtii: The precursor protein encoded by the cDNA contains both an N-terminal presequence and a C-terminal extension

cDNA and genomic clones encoding the subunit of mitochondrial ATP synthase from Chlamydomonas reinhardtii have been isolated using heterologous DNA probes from the photosynthetic bacterium Rhodospirillum rubrum. The protein encoded by the cDNA is 79–83% identical to corresponding proteins from higher-plant and mammalian mitochondria, and 75% identical to the R. rubrum protein. It contains both an N-terminal presequence and a unique C-terminal extension. The presequence, which is the first mitochondrial presequence determined in C. reinhardtii, is similar in structure to mitochondrial presequences from other organisms. As chloroplast presequences from C. reinhardtii also share features with mitochondrial presequences from other organisms (L.-G. Franzén et al., FEBS Lett 260 (1990) 165–168), this raises interesting questions about protein targeting to chloroplasts and mitochondria in C. reinhardtii. The possibility that the C-terminal extension is involved in targeting the protein to the mitochondrion is discussed. Southern blot analysis indicates that the protein is encoded by a single-copy gene.     

α-Synuclein overexpression impairs mitochondrial function by associating with adenylate translocator

α-Synuclein (α-syn), a protein involved in the pathogenesis of Parkinson's disease (PD), is known to accumulate in mitochondria, disrupt mitochondrial function. However, the molecular mechanisms that link these pathological responses have not been investigated. In rats overexpressing α-syn in the substantia nigra (SN) through adeno-associated virus (AAV) transduction, about 50% of tyrosine hydroxylase positive neurons were lost after 24 weeks. Overexpression of α-syn was also associated with morphological deformation of mitochondria and depolarization of the mitochondrial membrane potential (ΔΨm). Both co-immunoprecipitation and confocal microscopy demonstrated that mitochondrial α-syn associated with adenylate translocator (ANT), a component of the mitochondrial permeability transition pore (mPTP). The depolarization of ΔΨm was partially reversed in vitro by bongkrekic acid (BKA), an inhibitor of ANT, suggesting that the molecular association between α-syn and ANT facilitated ΔΨm depolarization. Concomitant with α-syn accumulation in mitochondria, abnormal mitochondrial morphology, ΔΨm depolarization, and loss of TH-positive neurons, there was a decrease in apoptosis-inducing factor (AIF) within the mitochondrial matrix, suggesting possible translocation to the cytosol. Our findings suggest that overexpression of α-syn may cause mitochondrial defects in dopaminergic neurons of the substantia nigra through an association with adenylate translocator and activation of mitochondria-dependent cell death pathways. Disruption of normal mitochondrial function may contribute to the loss of dopaminergic neurons in Parkinson's disease.     

The translocator maintenance protein Tam41 is required for mitochondrial cardiolipin biosynthesis

The mitochondrial inner membrane contains different translocator systems for the import of presequence-carrying proteins and carrier proteins. The translocator assembly and maintenance protein 41 (Tam41/mitochondrial matrix protein 37) was identified as a new member of the mitochondrial protein translocator systems by its role in maintaining the integrity and activity of the presequence translocase of the inner membrane (TIM23 complex). Here we demonstrate that the assembly of proteins imported by the carrier translocase, TIM22 complex, is even more strongly affected by the lack of Tam41. Moreover, respiratory chain supercomplexes and the inner membrane potential are impaired by lack of Tam41. The phenotype of Tam41-deficient mitochondria thus resembles that of mitochondria lacking cardiolipin. Indeed, we found that Tam41 is required for the biosynthesis of the dimeric phospholipid cardiolipin. The pleiotropic effects of the translocator maintenance protein on preprotein import and respiratory chain can be attributed to its role in biosynthesis of mitochondrial cardiolipin.     

Isolated plant mitochondria import chloroplast precursor proteins in vitro with the same efficiency as chloroplasts.

Most chloroplast and mitochondrial proteins are synthesized with N-terminal presequences that direct their import into the appropriate organelle. In this report we have analyzed the specificity of standard in vitro assays for import into isolated pea chloroplasts and mitochondria. We find that chloroplast protein import is highly specific because mitochondrial proteins are not imported to any detectable levels. Surprisingly, however, pea mitochondria import a range of chloroplast protein precursors with the same efficiency as chloroplasts, including those of plastocyanin, the 33-kDa photosystem II protein, Hcf136, and coproporphyrinogen III oxidase. These import reactions are dependent on the Deltaphi across the inner mitochondrial membrane, and furthermore, marker enzyme assays and Western blotting studies exclude any import by contaminating chloroplasts in the preparation. The pea mitochondria specifically recognize information in the chloroplast-targeting presequences, because they also import a fusion comprising the presequence of coproporphyrinogen III oxidase linked to green fluorescent protein. However, the same construct is targeted exclusively into chloroplasts in vivo indicating that the in vitro mitochondrial import reactions are unphysiological, possibly because essential specificity factors are absent in these assays. Finally, we show that disruption of potential amphipathic helices in one presequence does not block import into pea mitochondria, indicating that other features are recognized.     

Biogenesis of rat mitochondrial citrate carrier (CIC): the N-terminal presequence facilitates the solubility of the preprotein but does not act as a targeting signal

Most mitochondrial preproteins carry a cleavable N-terminal presequence that mediates targeting to mitochondria and translocation across the mitochondrial membranes. In this study, we characterized the presequence of the citrate carrier (CIC, tricarboxylate carrier) of rat liver mitochondria. The CIC presequence was found to be dispensable both for targeting to mitochondria and insertion into the inner membrane. Unlike the presequence of the related phosphate carrier, fusion of the CIC presequence to the cytosolic enzyme dihydrofolate reductase did not confer mitochondrial targeting, indicating that the CIC presequence does not act as a targeting signal. However, the presequence was required to keep the CIC in a soluble state. Mature CIC lacking the presequence was prone to aggregation. We conclude that mitochondrial presequences do not necessarily act as mediators of targeting. In the case of the CIC, the presequence appears to determine the folding state of the preprotein.     

Role for the mitochondrial inner membrane in the maturation of the precursor to ornithine carbamyl transferase

The precursor to ornithine carbamyl transferase (pOCT) is cleaved at two N-terminal sites when imported into intact mitochondria but only at the N-proximal site when incubated with a membrane-free mitochondrial lysate or matrix fraction. Disruption of the mitochondrial membrane system by sonication, freeze-thaw, or lysis with non-ionic detergents blocks the processing of pOCT to its mature form. Mitoplasts prepared from protease-inactivated, import-incompetent mitochondria recover full processing activity; disruption of the inner membrane impairs the maturation process i.e. causes the loss of the mitoplasts' ability to transform pOCT into OCT. The data reveal a dependency of a maturation event on a "specific" interaction between a precursor protein and the mitochondrial inner membrane probably to position and/or to expose the correct N-distal cleavage site of the presequence.     

The Tom40 assembly process probed using the attachment of different intramitochondrial sorting signals

The TOM40 complex is a protein translocator in the mitochondrial outer membrane and consists of several different subunits. Among them, Tom40 is a central subunit that constitutes a protein-conducting channel by forming a β-barrel structure. To probe the nature of the assembly process of Tom40 in the outer membrane, we attached various mitochondrial presequences to Tom40 that possess sorting information for the intermembrane space (IMS), inner membrane, and matrix and would compete with the inherent Tom40 assembly process. We analyzed the mitochondrial import of those fusion proteins in vitro. Tom40 crossed the outer membrane and/or inner membrane even in the presence of various sorting signals. N-terminal anchorage of the attached presequence to the inner membrane did not prevent Tom40 from associating with the TOB/SAM complex, although it impaired its efficient release from the TOB complex in vitro but not in vivo. The IMS or matrix-targeting presequence attached to Tom40 was effective in substituting for the requirement for small Tim proteins in the IMS for the translocation of Tom40 across the outer membrane. These results provide insight into the mechanism responsible for the precise delivery of β-barrel proteins to the outer mitochondrial membrane.     

The 5′-leader sequence of sugar beet mitochondrial <Emphasis Type="Italic">atp6</Emphasis> encodes a novel polypeptide that is characteristic of Owen cytoplasmic male sterility

Cytoplasmic male sterility (CMS) is a mitochondrially encoded trait, which is characterized by a failure of plants to produce viable pollen. We have investigated the protein profile of mitochondria from sugar beet plants with normal (fertile) or CMS cytoplasm, and observed that a 35-kDa polypeptide is expressed in Owen CMS plants but not in normal plants. The variant 35-kDa polypeptide was found in CMS mitochondria placed in five different nuclear backgrounds. Interestingly, this polypeptide proved to be antigenically related to a 387-codon ORF (preSatp6) that is fused in-frame with the downstream atp6. The presequence extension of the atp6 ORF is commonly found in higher plants, but whether or not it is normally expressed has hitherto remained unclear. Our study is thus the first to demonstrate that the atp6 presequence is actually translated in mitochondria. We also observed that preSATP6 is a mitochondrial membrane protein that assembles into a homogeneous 200-kDa protein complex. In organello translation experiments in the presence of protease inhibitors showed a reduction in the abundance of mature preSATP6 with time, suggesting that the mature preSATP6 may be derived by proteolytic processing of a translation product of the preSatp6/Satp6 ORF.     

Mitochondrial membrane permeabilization by HIV-1 Vpr

The mitochondrion is a privileged target for apoptosis-modulatory proteins of viral origin. Thus, viral protein R (Vpr) can target mitochondria and induce apoptosis via a specific interaction with the permeability transition pore complex (PTPC). Vpr cooperates with the adenine nucleotide translocator (ANT) to form large conductance channels and to trigger all the hallmarks of mitochondrial membrane permeabilization (MMP). The Vpr/ANT interaction is direct, since it is abolished by the addition of a peptide corresponding to the Vpr binding site of ANT, ADP, ATP, or by Bcl-2. Accordingly, Vpr modulates MMP through direct structural and functional interactions with PTPC proteins.     

Significance of the adenine nucleotide translocator in the pathogenesis of viral heart disease

We found recently autoantibodies against the adenine nucleotide translocator (ANT), a carrier in the inner mitochondrial membrane, in sera of patients with myocarditis and dilated cardiomyopathy. To elucidate whether these antibodies are of pathophysiological importance, we investigated the function and expression of the adenine nucleotide translocator (ANT) in the heart muscle tissue of patients suffering from myocarditis and DCM. We found a markedly lowered transport capacity of the translocator accompanied by an elevation in total ANT protein content. The alteration in ANT protein amount is caused by an ANT isoform shift characterized by an increase in ANT 1 isoform protein associated with a decrease in ANT 2 isoform and an unchanged ANT 3 content. It could be shown that the isoform shift is not a progressive process during the disease period but an event in the early period of illness which becomes permanent.Simulating the effect of pathogenetic factors of autoimmunological diseases, we infected A/J mice with the enterovirus Cox-sackie B3 and immunized guinea pigs with myocardial ANT protein. Both treatments led to autoimmunological responds and to a lowered myocardial transport capacity of ANT, to a disturbed energy metabolism and consequently to a depression of heart function.