Redundant mitochondrial targeting signals in yeast adenylate kinase

Yeast adenylate kinase (Aky2p, Adk1p) occurs simultaneously in cytoplasm and mitochondrial intermembrane space. It has no cleavable mitochondrial targeting sequence, and the signal for mitochondrial import and submitochondrial sorting is largely unknown. The extreme N terminus of Aky2p is able to direct cytoplasmic passengers to mitochondria. However, an Aky2 mutant lacking this sequence is imported with about the same efficiency as the wild type. To identify possible import-relevant information in the interior, parts of Aky2p were exchanged by homologous in vitro recombination for the respective segments of the purely cytoplasmic isozyme, Ura6p. Import studies revealed an internal region of about 40 amino acids, which was sufficient to direct the chimera to mitochondria but not for correct submitochondrial sorting. The respective Ura6p hybrid was arrested in the mitochondrial membrane at a position where it was inaccessible to protease but was released by alkaline extraction, suggesting that it had entered an import channel and passed the initial steps of recognition and uptake. Site-specific mutations within the presumptive address-specifying segment identified the amphipathic helix 5. A Ura6 mutant protein in which helix 5 had been replaced with the respective sequence from Aky2p was imported, and this address sequence cooperates with the N terminus in the respective double mutant in a synergistic fashion.     

Requirements for the mitochondrial import and localization of dihydroorotate dehydrogenase.

In animals, dihydroorotate dehydrogenase (DHODH) is a mitochondrial protein that carries out the fourth step in de novo pyrimidine biosynthesis. Because this is the only enzyme of this pathway that is localized to mitochondria and because the enzyme is cytosolic in some bacteria and fungi, we carried out studies to understand the mode of targeting of animal DHODH and its submitochondrial localization. Analysis of fractionated rat liver mitochondria revealed that DHODH is an integral membrane protein exposed to the intermembrane space. In vitro-synthesized Drosophila, rat and human DHODH proteins were efficiently imported into the intermembrane space of isolated yeast mitochondria. Import did not alter the size of the in vitro synthesized protein, nor was there a detectable size difference when compared to the DHODH protein found in vivo. Thus, there is no apparent proteolytic processing of the protein during import either in vitro or in vivo. Import of rat DHODH into isolated yeast mitochondria required inner membrane potential and was at least partially dependent upon matrix ATP, indicating that its localization uses the well described import machinery of the mitochondrial inner membrane. The DHODH proteins of animals differ from the cytosolic proteins found in some bacteria and fungi by the presence of an N-terminal segment that resembles mitochondrial-targeting presequences. Deletion of the cationic portion of this N-terminal sequence from the rat DHODH protein blocked its import into isolated yeast mitochondria, whereas deletion of the adjacent hydrophobic segment resulted in import of the protein into the matrix. Thus, the N-terminus of the DHODH protein contains a bipartite signal that governs import and correct insertion into the mitochondrial inner membrane.     

Transport of proteins to the mitochondrial intermembrane space: the ''sorting'' domain of the cytochrome c1 presequence is a stop-transfer sequence specific for the mitochondrial inner membrane.

The presequence of yeast cytochrome c1 (an inner membrane protein protruding into the intermembrane space) contains a matrix-targeting domain and an intramitochondrial sorting domain. This presequence transports attached subunit IV of cytochrome c oxidase into the intermembrane space (van Loon et al. (1987) EMBO J., 6, 2433-2439). In order to determine how this fusion protein reaches the intermembrane space, we studied the kinetics of its import into isolated mitochondria or mitoplasts and its accumulation in the various submitochondrial compartments. The imported, uncleaved fusion precursor and a cleavage intermediate were bound to the inner membrane and were always exposed to the intermembrane space; they were never found at the matrix side of the inner membrane. In contrast, analogous import experiments with the authentic subunit IV precursor, or the precursor of the iron-sulphur protein of the cytochrome bc1 complex also an inner membrane protein exposed to the intermembrane space), readily showed that these precursors were initially transported across both mitochondrial membranes. We conclude that the intramitochondrial sorting domain within the cytochrome c1 presequence prevents transport of attached proteins across the inner, but not the outer membrane: it is a stop-transfer sequence for the inner membrane. Since the presequence of the iron-sulphur protein lacks such 'stop-transfer' domain, it acts by a different mechanism.     

Characteristics of mitochondrial calpains

Calpains are considered to be cytoplasmic enzymes, although several studies have shown that calpain-like protease activities also exist in mitochondria. We partially purified mitochondrial calpain from swine liver mitochondria and characterized. Only one type of mitochondrial calpain was detected by the column chromatographies. The mitochondrial calpain was stained with anti-mu-calpain and calpain small subunit antibodies. The susceptibility of mitochondrial calpain to calpain inhibitors and the optimum pH differ from those of cytosolic mu- and m-calpains. The Ca(2+)-dependency of mitochondrial calpain was similar to that of cytosolic mu-calpain. Therefore, we named the protease mitochondrial mu-like calpain. In zymogram analysis, two types of caseinolytic enzymes existed in mitochondria and showed different mobilities from cytosolic mu- and m-calpains. The upper major band was stained with anti-mu-calpain and calpain small subunit antibodies (mitochondrial calpain I, mitochondrial mu-like calpain). The lower band was stained only with anti-calpain small subunit antibody (mitochondrial calpain II, unknown mitochondrial calpain). Calpastatin was not detected in mitochondrial compartments. The mitochondrial calpain processed apoptosis-inducing factor (AIF) to truncated AIF (tAIF), releasing tAIF into the intermembrane space. These results indicate that mitochondrial calpain, which differs from mu- and m-calpains, seems to be a ubiquitous calpain and may play a role in mitochondrial apoptotic signalling.     

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.     

Mammalian Oxa1 protein is useful for assessment of submitochondrial protein localization and mitochondrial membrane integrity

Taking advantage of the unique topology of oxidase assembly 1 (Oxa1) protein, a mitochondrial inner membrane protein with N (intermembrane space)-C (matrix) orientation, we explored the usefulness of the protein as a marker for submitochondrial protein localization. Mammalian Oxa1 protein exhibited different proteolytic patterns depending on mitochondrial membrane integrity, and in mitochondria with a disrupted outer membrane and outer and inner membranes, the proteolytic patterns of Oxa1 protein were consistent with those of mitochondrial intermembrane space and matrix marker proteins, respectively, suggesting that Oxa1 protein, a single molecule, can serve as a versatile submitochondrial localization marker that doubles as a membrane integrity marker.     

Identification of Tim40 that mediates protein sorting to the mitochondrial intermembrane space

Most mitochondrial proteins are synthesized in the cytosol, imported into mitochondria, and sorted to one of the four mitochondrial subcompartments. Here we identified a new inner membrane protein, Tim40, that mediates sorting of small Tim proteins to the intermembrane space. Tim40 is essential for yeast cell growth, and its function in vivo requires six conserved Cys residues but not anchoring of the protein to the inner membrane by its N-terminal hydrophobic segment. Depletion of Tim40 impairs the import of small Tim proteins into mitochondria both in vivo and in vitro. In wild-type mitochondria, Tim40 forms a translocation intermediate with small Tim proteins prior to their assembly in the intermembrane space in vitro. These results suggest the essential role of Tim40 in sorting/assembly of small Tim proteins.     

Import of cytochrome c heme lyase into mitochondria: a novel pathway into the intermembrane space.

Cytochrome c heme lyase (CCHL) catalyses the covalent attachment of the heme group to apocytochrome c during its import into mitochondria. The enzyme is membrane-associated and is located within the intermembrane space. The precursor of CCHL synthesized in vitro was efficiently translocated into isolated mitochondria from Neurospora crassa. The imported CCHL, like the native protein, was correctly localized to the intermembrane space, where it was membrane-bound. As with the majority of mitochondrial precursor proteins, CCHL uses the MOM19-GIP receptor complex in the outer membrane for import. In contrast to proteins taking the general import route, CCHL was imported independently of both ATP-hydrolysis and an electrochemical potential as external energy sources. CCHL which lacks a cleavable signal sequence apparently does not traverse the inner membrane to reach the intermembrane space; rather, it translocates through the outer membrane only. Thus, CCHL represents an example of a novel, 'non-conservative' import pathway into the intermembrane space, thereby also showing that the import apparatus in the outer membrane acts separately from the import machinery in the inner membrane.     

Acyl coenzyme A-binding protein augments bid-induced mitochondrial damage and cell death by activating mu-calpain

Activation of calpain has been shown to occur in some contexts of cell injury and to be essential for loss of cell viability. Part of this may be mediated at the mitochondrial level. It has been demonstrated that calpain activity is necessary for the complete discharge of apoptosis-inducing factor from the mitochondrial intermembrane space and can cause the cleavage of full-length Bid to a more potent truncated form (Polster, B. M., Basanez, G., Etxebarria, A., Hardwick, J. M., and Nicholls, D. G. (2005) J. Biol. Chem. 280, 6447-6454). In this study, we identify acyl-CoA-binding protein (ACBP) as playing a critical role in the activation of calpain upon exposure of mitochondria to both full-length Bid and truncated Bid (t-Bid). Suppression of ACBP levels by small interfering RNA inhibited the t-Bid-induced activation of mitochondrial mu-calpain and release of apoptosis-inducing factor from the mitochondrial intermembrane space and the cleavage of full-length Bid to t-Bid. Moreover, ACBP required the presence of the peripheral benzodiazepine receptor (for which ACBP is a ligand) to be retained at the mitochondria, to activate mu-calpain, and to amplify Bid-induced mitochondrial damage.     

Mitochondrial localization of mu-calpain

Calcium-dependent cysteine proteases, calpains, have physiological roles in cell motility and differentiation but also play a pathological role following insult or disease. The ubiquitous calpains are widely considered to be cytosolic enzymes, although there has been speculation of a mitochondrial calpain. Within a highly enriched fraction of mitochondria obtained from rat cortex and SH-SY5Y human neuroblastoma cells, immunoblotting demonstrated enrichment of the 80kDa mu-calpain large subunit and 28kDa small subunit. In rat cortex, antibodies against domains II and III of the large mu-calpain subunit also detected a 40kDa fragment, similar to the autolytic fragment generated following incubation of human erythrocyte mu-calpain with Ca(2+). Mitochondrial proteins including apoptosis inducing factor and mitochondrial Bax are calpain substrates, but the mechanism by which calpains gain access to these proteins is uncertain. Mitochondrial localization of mu-calpain places the enzyme in proximity to its mitochondrial substrates and to Ca(2+) released from mitochondrial stores.     

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.     

The first twelve amino acids (less than half of the pre-sequence) of an imported mitochondrial protein can direct mouse cytosolic dihydrofolate reductase into the yeast mitochondrial matrix.

Yeast cytochrome c oxidase subunit IV (an imported mitochondrial protein) is made as a larger precursor with a transient pre-sequence of 25 amino acids. If this pre-sequence is fused to the amino terminus of mouse dihydrofolate reductase (a cytosolic protein) the resulting fusion protein is imported into the matrix space, and cleaved to a smaller size, by isolated yeast mitochondria. We have now fused progressively shorter amino-terminal segments of the subunit IV pre-sequence to dihydrofolate reductase and tested each fusion protein for import into the matrix space and cleavage by the matrix-located processing protease. The first 12 amino acids of the subunit IV pre-sequence were sufficient to direct dihydrofolate reductase into the mitochondrial matrix, both in vitro and in vivo. However, import of the corresponding fusion protein into the matrix was no longer accompanied by proteolytic processing. Fusion proteins containing fewer than nine amino-terminal residues from the subunit IV pre-piece were not imported into isolated mitochondria. The information for transporting attached mouse dihydrofolate reductase into mitochondria is thus contained within the first 12 amino acids of the subunit IV pre-sequence.     

Assembly of imported subunit 8 into the ATP synthase complex of isolated yeast mitochondria

This study concerns the assembly into a multisubunit enzyme complex of a small hydrophobic protein imported into isolated mitochondria. Subunit 8 of yeast mitochondrial ATPase (normally a mitochondrial gene product) was expressed in vitro as a chimaeric precursor N9L/Y8-1, which includes an N-terminal-cleavable transit peptide to direct its import into mitochondria. Assembly into the enzyme complex of the imported subunit 8 was monitored by immunoadsorption using an immobilized anti-F1-beta monoclonal antibody. Preliminary experiments showed that N9L/Y8-1 imported into normal rho+ mitochondria, with its complement of fully assembled ATPase, did not lead to an appreciable assembly of the exogenous subunit 8. With the expectation that mitochondria previously depleted of subunit 8 could allow such assembly in vitro, target mitochondria were prepared from genetically modified yeast cells in which synthesis of subunit 8 was specifically blocked. Initially, mitochondria were prepared from strain M31, a mit- mutant completely incapable of intramitochondrial biosynthesis of subunit 8. These mit- mitochondria however were unsuitable for assembly studies because they could not import protein in vitro. A controlled depletion strategy was then evolved. An artificial nuclear gene encoding N9L/Y8-1 was brought under the control of a inducible promoter GAL1. This regulated gene construct, in a low copy number yeast expression vector, was introduced into strain M31 to generate strain YGL-1. Galactose control of the expression of N9L/Y8-1 was demonstrated by the ability of strain YGL-1 to grow vigorously on galactose as a carbon source, and by the inability to utilize ethanol alone for prolonged periods of growth. The measurement of bioenergetic parameters in mitochondria from YGL-1 cells experimentally depleted of subunit 8, by transferring growing cells from galactose to ethanol, was consistent with the presence in mitochondria of a mosaic of ATPase, namely fully assembled functional ATPase complexes and partially assembled complexes with defective F0 sectors. These mitochondria demonstrated very efficient import of N9L/Y8-1 and readily incorporated the imported processed subunit 8 protein into ATPase. Comparison of the kinetics of import and assembly of subunit 8 showed that assembly was noticeably delayed with respect to import. These findings open the way to a new systematic analysis of the assembly of imported proteins into multisubunit mitochondrial enzyme complexes.     

A new function in translocation for the mitochondrial i-AAA protease Yme1: import of polynucleotide phosphorylase into the intermembrane space

Polynucleotide phosphorylase (PNPase) is an exoribonuclease and poly(A) polymerase postulated to function in the cytosol and mitochondrial matrix. Prior overexpression studies resulted in PNPase localization to both the cytosol and mitochondria, concurrent with cytosolic RNA degradation and pleiotropic cellular effects, including growth inhibition and apoptosis, that may not reflect a physiologic role for endogenous PNPase. We therefore conducted a mechanistic study of PNPase biogenesis in the mitochondrion. Interestingly, PNPase is localized to the intermembrane space by a novel import pathway. PNPase has a typical N-terminal targeting sequence that is cleaved by the matrix processing peptidase when PNPase engaged the TIM23 translocon at the inner membrane. The i-AAA protease Yme1 mediated translocation of PNPase into the intermembrane space but did not degrade PNPase. In a yeast strain deleted for Yme1 and expressing PNPase, nonimported PNPase accumulated in the cytosol, confirming an in vivo role for Yme1 in PNPase maturation. PNPase localization to the mitochondrial intermembrane space suggests a unique role distinct from its highly conserved function in RNA processing in chloroplasts and bacteria. Furthermore, Yme1 has a new function in protein translocation, indicating that the intermembrane space harbors diverse pathways for protein translocation.     

Import into mitochondria of precursors containing hydrophobic passenger proteins: pretreatment of precursors with urea inhibits import

We have studied the import into isolated yeast mitochondria of three hydrophobic passenger proteins attached to the N-terminal cleavable presequence of mitochondrial ATPase subunit 9 from Neurospora crassa. One natural precursor (pN9) contained N. crassa subunit 9; two chimaeric precursors, N9L/Y8-1 and N9L/Y9-2, respectively contained yeast mitochondrial ATPase subunits 8 and 9. In the absence of urea, pN9 and N9L/Y8-1 are imported efficiently but N9L/Y9-2 is not imported. After pretreatment of precursors in 4 M urea, binding of pN9 to mitochondria is marginally affected while its import is substantially inhibited; the binding to mitochondria of chimaeric proteins, N9L/Y8-1 and N9L/Y9-2, is greatly enhanced but no import is observed. This behaviour of import precursors containing hydrophobic passenger proteins is contrasted with that of a hydrophilic chimaeric precursor pCOXIV-DHFR, whose binding and import are enhanced by pretreatment with a high concentration of urea (8 M). The import of N9L/Y8-1 is very sensitive to the presence of low concentrations of urea in the import reaction mixture, and is abolished above 0.5 M urea although precursor binding to mitochondria is increased. By contrast, neither the import nor binding of pCOXIV-DHFR is affected directly by urea up to 0.8 M. These deleterious effects of urea on import of the chimaeric precursors N9L/Y8-1 and N9L/Y9-2 are interpreted in terms of a non-productive binding of these precursors to mitochondria, brought about by exposure of their hydrophobic domains resulting from urea unfolding. The generalization that membrane translocation of mitochondrial import precursors is enhanced by their prior unfolding in urea thus does not apply in the case of these precursors containing hydrophobic passenger proteins.     

Intramitochondrial sorting of the precursor to yeast cytochrome c oxidase subunit Va

We have continued our studies on the import pathway of the precursor to yeast cytochrome c oxidase subunit Va (pVa), a mitochondrial inner membrane protein. Previous work on this precursor demonstrated that import of pVa is unusually efficient, and that inner membrane localization is directed by a membrane-spanning domain in the COOH- terminal third of the protein. Here we report the results of studies aimed at analyzing the intramitochondrial sorting of pVa, as well as the role played by ancillary factors in import and localization of the precursor. We found that pVa was efficiently imported and correctly sorted in mitochondria prepared from yeast strains defective in the function of either mitochondrial heat shock protein (hsp)60 or hsp70. Under identical conditions the import and sorting of another mitochondrial protein, the precursor to the beta subunit of the F1 ATPase, was completely defective. Consistent with previous results demonstrating that the subunit Va precursor is loosely folded, we found that pVa could be efficiently imported into mitochondria after translation in wheat germ extracts. This results suggests that normal levels of extramitochondrial hsp70 are also not required for import of the protein. The results of this study enhance our understanding of the mechanism by which pVa is routed to the mitochondrial inner membrane. They suggest that while the NH2 terminus of pVa is exposed to the matrix and processed by the matrix metalloprotease, the protein remains anchored to the inner membrane before being assembled into a functional holoenzyme complex.     

Mitochondrial preprotein translocases as dynamic molecular machines

Proteomic studies have demonstrated that yeast mitochondria contain roughly 1000 different proteins. Only eight of these proteins are encoded by the mitochondrial genome and are synthesized on mitochondrial ribosomes. The remaining 99% of mitochondrial precursors are encoded within the nuclear genome and after their synthesis on cytosolic ribosomes must be imported into the organelle. Targeting of these proteins to mitochondria and their import into one of the four mitochondrial subcompartments--outer membrane, intermembrane space (IMS), inner membrane and matrix--requires various membrane-embedded protein translocases, as well as numerous chaperones and cochaperones in the aqueous compartments. During the last years, several novel protein components involved in the import and assembly of mitochondrial proteins have been identified. The picture that emerges from these exciting new findings is that of highly dynamic import machineries, rather than of regulated, but static protein complexes. In this review, we will give an overview on the recent progress in our understanding of mitochondrial protein import. We will focus on the presequence translocase of the inner mitochondrial membrane, the TIM23 complex and the presequence translocase-associated motor, the PAM complex. These two molecular machineries mediate the multistep import of preproteins with cleavable N-terminal signal sequences into the matrix or inner membrane of mitochondria.     

Analysis of the sorting signals directing NADH-cytochrome b5 reductase to two locations within yeast mitochondria.

Mitochondrial NADH-cytochrome b5 reductase (Mcr1p) is encoded by a single nuclear gene and imported into two different submitochondrial compartments: the outer membrane and the intermembrane space. We now show that the amino-terminal 47 amino acids suffice to target the Mcr1 protein to both destinations. The first 12 residues of this sequence function as a weak matrix-targeting signal; the remaining residues are mostly hydrophobic and serve as an intramitochondrial sorting signal for the outer membrane and the intermembrane space. A double point mutation within the hydrophobic region of the targeting sequence virtually abolishes the ability of the precursor to be inserted into the outer membrane but increases the efficiency of transport into the intermembrane space. Import of Mcr1p into the intermembrane space requires an electrochemical potential across the inner membrane, as well as ATP in the matrix, and is strongly impaired in mitochondria lacking Tom7p or Tim11p, two components of the translocation machineries in the outer and inner mitochondrial membranes, respectively. These results indicate that intramitochondrial sorting of the Mcr1 protein is mediated by specific interactions between the bipartite targeting sequence and components of both mitochondrial translocation systems.     

Pink1 kinase and its membrane potential (Deltaψ)-dependent cleavage product both localize to outer mitochondrial membrane by unique targeting mode

The Parkinson disease-associated kinase Pink1 is targeted to mitochondria where it is thought to regulate mitochondrial quality control by promoting the selective autophagic removal of dysfunctional mitochondria. Nevertheless, the targeting mode of Pink1 and its submitochondrial localization are still not conclusively resolved. The aim of this study was to dissect the mitochondrial import pathway of Pink1 by use of a highly sensitive in vitro assay. Mutational analysis of the Pink1 sequence revealed that its N terminus acts as a genuine matrix localization sequence that mediates the initial membrane potential (Δψ)-dependent targeting of the Pink1 precursor to the inner mitochondrial membrane, but it is dispensable for Pink1 import or processing. A hydrophobic segment downstream of the signal sequence impeded complete translocation of Pink1 across the mitochondrial inner membrane. Additionally, the C-terminal end of the protein promoted the retention of Pink1 at the outer membrane. Thus, multiple targeting signals featured by the Pink1 sequence result in the final localization of both the full-length protein and its major Δψ-dependent cleavage product to the cytosolic face of the outer mitochondrial membrane. Full-length Pink1 and deletion constructs resembling the natural Pink1 processing product were found to assemble into membrane potential-sensitive high molecular weight protein complexes at the mitochondrial surface and displayed similar cytoprotective effects when expressed in vivo, indicating that both species are functionally relevant.     

Insertion into the mitochondrial inner membrane of a polytopic protein, the nuclear-encoded Oxa1p.

Oxa1p, a nuclear-encoded protein of the mitochondrial inner membrane with five predicted transmembrane (TM) segments is synthesized as a precursor (pOxa1p) with an N-terminal presequence. It becomes imported in a process requiring the membrane potential, matrix ATP, mt-Hsp70 and the mitochondrial processing peptidase (MPP). After processing, the negatively charged N-terminus of Oxa1p (approximately 90 amino acid residues) is translocated back across the inner membrane into the intermembrane space and thereby attains its native N(out)-C(in) orientation. This export event is dependent on the membrane potential. Chimeric preproteins containing N-terminal stretches of increasing lengths of Oxa1p fused on mouse dehydrofolate reductase (DHFR) were imported into isolated mitochondria. In each case, their DHFR moieties crossed the inner membrane into the matrix. Thus Oxa1p apparently does not contain a stop transfer signal. Instead the TM segments are inserted into the membrane from the matrix side in a pairwise fashion. The sorting pathway of pOxa1p is suggested to combine the pathways of general import into the matrix with a bacterial-type export process. We postulate that at least two different sorting pathways exist in mitochondria for polytopic inner membrane proteins, the evolutionarily novel pathway for members of the ADP/ATP carrier family and a conserved Oxa1p-type pathway.