Mitochondrial precursor proteins are imported through a hydrophilic membrane environment

We have analyzed how translocation intermediates of imported mitochondrial precursor proteins, which span contact sites, interact with the mitochondrial membranes. F1-ATPase subunit beta (F1 beta) was trapped at contact sites by importing it into Neurospora mitochondria in the presence of low levels of nucleoside triphosphates. This F1 beta translocation intermediate could be extracted from the membranes by treatment with protein denaturants such as alkaline pH or urea. By performing import at low temperatures, the ADP/ATP carrier was accumulated in contact sites of Neurospora mitochondria and cytochrome b2 in contact sites of yeast mitochondria. These translocation intermediates were also extractable from the membranes at alkaline pH. Thus, translocation of precursor proteins across mitochondrial membranes seems to occur through an environment which is accessible to aqueous perturbants. We propose that proteinaceous structures are essential components of a translocation apparatus present in contact sites.     

Sequential translocation of an artificial precursor protein across the two mitochondrial membranes.

We have constructed a chimeric mitochondrial precursor protein consisting of a mutant bovine pancreatic trypsin inhibitor coupled to the C terminus of a purified artificial precursor protein. This construct fails to complete its import into isolated mitochondria and becomes stuck across sites of close contact between the two mitochondrial membranes. When the mitochondria are then depleted of ATP and the intramolecular disulfide bridges of the trypsin inhibitor are cleaved by dithiothreitol, the trypsin inhibitor moiety is transported across the outer membrane into the intermembrane space. This translocation intermediate can be chased across the inner membrane by restoring the ATP levels in the matrix. These results show that translocation of pancreatic trypsin inhibitor across a biological membrane is prevented by its intramolecular disulfide bridges, that import into the matrix involves two distinct translocation system operating in tandem, and that ATP is required for protein translocation across the inner but not the outer membrane.     

The alpha and the beta: protein translocation across mitochondrial and plastid outer membranes

In the evolution of mitochondria and plastids from endosymbiotic bacteria, most of the proteins that make up these organelles have become encoded by nuclear genes and must therefore be transported across the organellar membranes, following synthesis in the cytosol. The core component of the protein translocation machines in both the mitochondrial and plastid outer membranes appears to be a beta-barrel protein, perhaps a relic from their bacterial ancestry, distinguishing these translocases from the alpha-helical-based protein translocation pores found in all other eukaryotic membranes.     

tRNA import across the mitochondrial inner membrane in T. brucei requires TIM subunits but is independent of protein import

Mitochondrial tRNA import is widespread, but mechanistic insights of how tRNAs are translocated across mitochondrial membranes remain scarce. The parasitic protozoan T. brucei lacks mitochondrial tRNA genes. Consequently, it imports all organellar tRNAs from the cytosol. Here we investigated the connection between tRNA and protein translocation across the mitochondrial inner membrane. Trypanosomes have a single inner membrane protein translocase that consists of three heterooligomeric submodules, which all are required for import of matrix proteins. In vivo depletion of individual submodules shows that surprisingly only the integral membrane core module, including the protein import pore, but not the presequence-associated import motor are required for mitochondrial tRNA import. Thus we could uncouple import of matrix proteins from import of tRNAs even though both substrates are imported into the same mitochondrial subcompartment. This is reminiscent to the outer membrane where the main protein translocase but not on-going protein translocation is required for tRNA import. We also show that import of tRNAs across the outer and inner membranes are coupled to each other. Taken together, these data support the ‘alternate import model’, which states that tRNA and protein import while mechanistically independent use the same translocation pores but not at the same time.     

Protein translocation into mitochondria

The biogenesis of mitochondria requires the translocation of most mitochondrial proteins across two biological membranes. Mitochondrial preproteins are synthesized in the cytosol carrying targeting information, that is recognized by specific receptor proteins. The precursor polypeptides are transported across both mitochondrial membranes via three large integral membrane protein complexes forming specialized preprotein translocases. A soluble protein complex in the matrix provides the ATP-dependent translocation force, responsible for the movement and unfolding of the bulk polypeptide chain. After the removal of the targeting sequence, imported proteins fold into their native conformation with the help of chaperone proteins in the mitochondrial matrix.     

The Mitochondrial Protein Import Pathway: Are Precursors Imported through Membrane Channels?

Mitochondrial biogenesis requires the import of hundreds of different proteins from the cytosol. Protein import into mitochondria is a multistep pathway that includes recognition of precursor proteins by machinery both in the cytoplasm and on the mitochondrial surface, translocation of the precursor across one or both mitochondrial membranes, and folding of the protein after its import into the organelle. Over the past several years, many components of the import machinery have been identified using both biochemical and genetic methods. Recently, significant progress has been made determining the function of some of these import proteins. One purpose of this minireview is to summarize our current understanding of the import pathway, and to introduce the topics of the minireviews that will follow. The other goal of this minireview is to discuss recent findings suggesting that proteins are translocated across both the mitochondrial inner and outer membranes through aqueous channels.     

The essential yeast protein MIM44 (encoded by MPI1) is involved in an early step of preprotein translocation across the mitochondrial inner membrane.

The essential yeast gene MPI1 encodes a mitochondrial membrane protein that is possibly involved in protein import into the organelle (A. C. Maarse, J. Blom, L. A. Grivell, and M. Meijer, EMBO J. 11:3619-3628, 1992). For this report, we determined the submitochondrial location of the MPI1 gene product and investigated whether it plays a direct role in the translocation of preproteins. By fractionation of mitochondria, the mature protein of 44 kDa was localized to the mitochondrial inner membrane and therefore termed MIM44. Import of the precursor of MIM44 required a membrane potential across the inner membrane and involved proteolytic processing of the precursor. A preprotein in transit across the mitochondrial membranes was cross-linked to MIM44, whereas preproteins arrested on the mitochondrial surface or fully imported proteins were not cross-linked. When preproteins were arrested at two distinct stages of translocation across the inner membrane, only preproteins at an early stage of translocation could be cross-linked to MIM44. Moreover, solubilized MIM44 was found to interact with in vitro-synthesized preproteins. We conclude that MIM44 is a component of the mitochondrial inner membrane import machinery and interacts with preproteins in an early step of translocation.     

Studies on the lipid dependency and mechanism of the translocation of the mitochondrial precursor protein apocytochrome c across model membranes

The lipid dependency of apocytochrome c binding to model membranes and of the translocation of the precursor protein across these membranes was studied by using large unilamellar, trypsin-containing vesicles. These vesicles were improved with respect to those used in a previous article (Rietveld, A., and de Kruijff, B. (1984) J. Biol. Chem. 259, 6704-6706), in the sense that a lower amount of trypsin was enclosed. In mixed egg phosphatidylcholine/bovine brain phosphatidylserine vesicles, both the Kd of apocytochrome c binding (about 20 microM) and the number of phosphatidylserine molecules interacting with the protein was found to be constant. When the phosphatidylserine fraction in the vesicles is more than 15-30% apocytochrome c addition results in the exposure of (a part of) the protein to the internal, trypsin-containing vesicle medium, which process we conceive as a translocation event. Also the interaction of apocytochrome c with vesicles composed of phosphatidylcholine and another acidic phospholipid in a 1:1 ratio, leads to the translocation of the protein across the model membrane. The affinity of this binding was found to be in the order cardiolipin greater than phosphatidylglycerol greater than phosphatidylinositol greater than phosphatidylserine. By varying the lipid composition of the vesicles, it could be demonstrated that the translocation requires a fluid bilayer. In addition, protein specificity was shown for the translocation process. Although apocytochrome c-lipid interaction causes vesicle aggregation, fusion by lipid mixing could not be detected. Due to the apocytochrome c-lipid interaction also, protein aggregates and oligomers have been formed. These results will be discussed in the light of a model for translocation of a precursor protein across a model membrane. The relevance for the mitochondrial system will also be discussed.     

Phenethyl alcohol disorders phospholipid acyl chains and promotes translocation of the mitochondrial precursor protein apocytochrome c across a lipid bilayer.

The interaction of phenethyl alcohol with model membranes and its effect on translocation of the chemically prepared mitochondrial precursor protein apocytochrome c across a lipid bilayer was studied. Phenethyl alcohol efficiently penetrates into monolayers and causes acyl chain disordering judged from deuterium nuclear magnetic resonance measurements with specific acyl chain-deuterated phospholipids. Translocation of apocytochrome c across a phospholipid bilayer was stimulated on addition of phenethyl alcohol indicating that the efficiency of translocation of this precursor protein is enhanced due to a disorder of the acyl chain region of the bilayer.     

Mitochondrial protein biogenesis: The essential functions of chaperones and their cofactors during preprotein translocation

Most mitochondrial proteins have to be imported from the cytosol through both mitochondrial membranes to their final localization. A dedicated translocation machinery is responsible for the specific recognition and the membrane transport of mitochondrial precursor proteins. Protein translocase complexes integrated into both mitochondrial membranes cooperate closely with receptor proteins at the surface and provide aqueous transport channels through the membranes. Energy for the membrane insertion is provided by the electric potential across the mitochondrial inner membrane. However, full translocation of the polypeptide chain requires ATP hydrolysis in the matrix. The responsible ATPase enzyme is a member of an ubiquitous family of molecular chaperones, the mitochondrial heat shock protein of 70 kDa (mtHsp70). A physical and functional interaction with a set of cofactors is indispensable for the translocation function of mtHsp70. By a specific and nucleotide-dependent binding to the inner membrane translocase component Tim44, the soluble chaperone mtHsp70 is anchored directly at the site of preprotein membrane insertion. The nucleotide exchange factor Mge1 enhances the ATPase activity of mtHsp70 and is required for the preprotein import reaction. Two novel proteins, Pam18 and Pam16, members of the inner membrane translocation channel, are required to couple the ATPase activity of mtHsp70 to the preprotein import reaction. We have collected experimental evidence indicating that mtHsp70 generates an inward directed translocation force on the polypeptide chain in transit by an ATP-regulated direct interaction with the precursor protein. The force generation results in the movement and active unfolding of the preprotein domains during the translocation process. Taken together, the chaperone mtHsp70 with its accessory proteine forms an import motor complex for mitochondrial preproteins that is driven by the hydrolysis of ATP.     

A dual role for mitochondrial heat shock protein 70 in membrane translocation of preproteins

The role of mitochondrial 70-kD heat shock protein (mt-hsp70) in protein translocation across both the outer and inner mitochondrial membranes was studied using two temperature-sensitive yeast mutants. The degree of polypeptide translocation into the matrix of mutant mitochondria was analyzed using a matrix-targeted preprotein that was cleaved twice by the processing peptidase. A short amino-terminal segment of the preprotein (40-60 amino acids) was driven into the matrix by the membrane potential, independent of hsp70 function, allowing a single cleavage of the presequence. Artificial unfolding of the preprotein allowed complete translocation into the matrix in the case where mutant mt-hsp70 had detectable binding activity. However, in the mutant mitochondria in which binding to mt-hsp70 could not be detected the mature part of the preprotein was only translocated to the intermembrane space. We propose that mt-hsp70 fulfills a dual role in membrane translocation of preproteins. (a) Mt-hsp70 facilitates unfolding of the polypeptide chain for translocation across the mitochondrial membranes. (b) Binding of mt-hsp70 to the polypeptide chain is essential for driving the completion of transport of a matrix- targeted preprotein across the inner membrane. This second role is independent of the folding state of the preprotein, thus identifying mt- hsp70 as a genuine component of the inner membrane translocation machinery. Furthermore we determined the sites of the mutations and show that both a functional ATPase domain and ATP are needed for mt- hsp70 to bind to the polypeptide chain and drive its translocation into the matrix.     

Embedded or not? Hydrophobic sequences and membranes

The same translocation machinery appears to be responsible for both the translocation of soluble proteins across membranes and the insertion of integral membrane proteins into the bilayer. A single mechanism is proposed to accommodate these two functions. This model is also extended to explain the paradoxical translocation of mitochondrial and chloroplastic membrane proteins across one or more membranes before they are finally inserted into their target membranes.     

The carboxyl-terminal third of the dicarboxylate carrier is crucial for productive association with the inner membrane twin-pore translocase

The carrier proteins of the mitochondrial inner membrane consist of three structurally related tandem repeats (modules). Several different, and in some cases contradictory, views exist on the role individual modules play in carrier transport across the mitochondrial membranes and how they promote protein insertion into the inner membrane. Thus, by use of specific translocation intermediates, we performed a detailed analysis of carrier biogenesis and assessed the physical association of carrier modules with the inner membrane translocation machinery. Here we have reported that each module of the dicarboxylate carrier contains sufficient targeting information for its transport across the outer mitochondrial membrane. The carboxyl-terminal module possesses major targeting information to facilitate the direct binding of the carrier protein to the inner membrane twin-pore translocase and subsequent insertion into the inner membrane in a membrane potential-dependent manner. We concluded that, in this case, a single structural repeat can drive inner membrane insertion, whereas all three related units contribute targeting information for outer membrane translocation.     

Gene expression of D-beta-hydroxybutyrate dehydrogenase. II. Incorporation of pre-BDH into mitochondria

beta-hydroxybutyrate dehydrogenase (BDH), a major protein located in the inner mitochondrial membrane is encoded, as most of mitochondrial proteins, in the nuclear genome. It is synthetized on the free polysomes and post-translationally imported into the mitochondria. The neosynthesized protein is a higher molecular weight precursor. The presequence is cleaved by the matrix protease to give the mature protein. The translocation across the mitochondrial membranes needs energy. The results also indicate that cytosolic factors with low molecular weight are essential in the recognition of precursor by mitochondria and to sort out newly synthetized nuclear encoded mitochondrial proteins from others nuclear encoded proteins.     

Calcium depletion and calmodulin inhibition affect the import of nuclear-encoded proteins into plant mitochondria

Many metabolic processes essential for plant viability take place in mitochondria. Therefore, mitochondrial function has to be carefully balanced in accordance with the developmental stage and metabolic requirements of the cell. One way to adapt organellar function is the alteration of protein composition. Since most mitochondrial proteins are nuclear encoded, fine-tuning of mitochondrial protein content could be achieved by the regulation of protein translocation. Here we present evidence that the import of nuclear-encoded mitochondrial proteins into plant mitochondria is influenced by calcium and calmodulin. In pea mitochondria, the calmodulin inhibitor ophiobolin A as well as the calcium ionophores A23187 and ionomycin inhibit translocation of nuclear-encoded proteins in a concentration-dependent manner, an effect that can be countered by the addition of external calmodulin or calcium, respectively. Inhibition was observed exclusively for proteins translocating into or across the inner membrane but not for proteins residing in the outer membrane or the intermembrane space. Ophiobolin A and the calcium ionophores further inhibit translocation into mitochondria with disrupted outer membranes, but their effect is not mediated via a change in the membrane potential across the inner mitochondrial membrane. Together, our results suggest that calcium/calmodulin influences the import of a subset of mitochondrial proteins at the inner membrane. Interestingly, we could not observe any influence of ophiobolin A or the calcium ionophores on protein translocation into mitochondria of yeast, indicating that the effect of calcium/calmodulin on mitochondrial protein import might be a plant-specific trait.     

The role of topogenic sequences in the movement of proteins through membranes.

Recent advances have led to considerable convergence in ideas of the way topogenic sequences act to translocate proteins across various intracellular membranes (Table 2). Whereas co-translational translocation and processing were previously considered the norm at the endoplasmic reticulum membrane, several instances of post-translational translocation into endoplasmic reticulum microsomes in vitro have now been described. However, it must be noted that post-translational translocation in vitro is much less efficient than when endoplasmic reticulum membranes are present during translation, and it is possible that in the intact cell translocation occurs during translation. Movement of proteins into chloroplasts and mitochondria occurs after translation. When translocation is post-translational, proteins may perhaps traverse the membrane as folded domains, and the conformational effects of topogenic sequences on these domains may be as envisaged in Wickner's 'membrane-trigger hypothesis'. Both signal and transit sequences possess amphipathic structures which are capable of interacting with phospholipid bilayers, and these interactions may disturb the bilayer sufficiently to allow entry of the following domains of protein. There is increasing evidence that GTP is required to bind ribosomes and their associated nascent chains to the endoplasmic reticulum membrane. Precisely how the cell's energy is applied to achieve translocation is not clear, but one possibility at the endoplasmic reticulum is that a GTP-hydrolysing transducing mechanism may exist to couple signal sequence receptor binding to movement of the nascent chain across the membrane. Electrochemical gradients are required for protein movement to the mitochondrial inner membrane and across the bacterial inner membrane. Cytoplasmic factors such as SRP, the secA gene product or a 40 kDa protein (for mitochondrial precursors) may act by binding to topogenic sequences and preventing precursor proteins as they are translated from folding into forms which cannot be translocated. Specificity in the cell may be achieved both by targetting interactions between these cytoplasmic factors and their receptors located in target membranes, and also by specific binding of the topogenic sequences to specific proteins integrated into the target membranes. Possible candidates for the latter are the protein of microsomal membranes that reacts with a photoreactive signal peptide to give a 45 kDa complex (Fig. 1), the secY gene product of the bacterial inner membrane, and receptors on the outer membranes of chloroplasts and mitochondria. Whether these aid translocation as well as recognition is not clear.(ABSTRACT TRUNCATED AT 400 WORDS)     

Translocation and insertion of precursor proteins into isolated outer membranes of mitochondria

Nuclear-encoded proteins destined for mitochondria must cross the outer or both outer and inner membranes to reach their final sub- mitochondrial locations. While the inner membrane can translocate preproteins by itself, it is not known whether the outer membrane also contains an endogenous protein translocation activity which can function independently of the inner membrane. To selectively study the protein transport into and across the outer membrane of Neurospora crassa mitochondria, outer membrane vesicles were isolated which were sealed, in a right-side-out orientation, and virtually free of inner membranes. The vesicles were functional in the insertion and assembly of various outer membrane proteins such as porin, MOM19, and MOM22. Like with intact mitochondria, import into isolated outer membranes was dependent on protease-sensitive surface receptors and led to correct folding and membrane integration. The vesicles were also capable of importing a peripheral component of the inner membrane, cytochrome c heme lyase (CCHL), in a receptor-dependent fashion. Thus, the protein translocation machinery of the outer mitochondrial membrane can function as an independent entity which recognizes, inserts, and translocates mitochondrial preproteins of the outer membrane and the intermembrane space. In contrast, proteins which have to be translocated into or across the inner membrane were only specifically bound to the vesicles, but not imported. This suggests that transport of such proteins involves the participation of components of the intermembrane space and/or the inner membrane, and that in these cases the outer membrane translocation machinery has to act in concert with that of the inner membrane.     

Mitochondrial protein import: two membranes,three translocases

Most mitochondrial proteins are synthesised in the cytosol and must be translocated across one or two membranes to reach their functional destination inside mitochondria. Dynamic protein complexes in the outer and inner membranes function as specific machineries that recognise the various kinds of precursor proteins and promote their translocation through protein-conducting channels. At least three major translocase complexes with a high flexibility and versatility are needed to ensure the proper import of precursor proteins into mitochondria.     

Cyclophilin 20 is involved in mitochondrial protein folding in cooperation with molecular chaperones Hsp70 and Hsp60.

We studied the role of mitochondrial cyclophilin 20 (CyP20), a peptidyl-prolyl cis-trans isomerase, in preprotein translocation across the mitochondrial membranes and protein folding inside the organelle. The inhibitory drug cyclosporin A did not impair membrane translocation of preproteins, but it delayed the folding of an imported protein in wild-type mitochondria. Similarly, Neurospora crassa mitochondria lacking CyP20 efficiently imported preproteins into the matrix, but folding of an imported protein was significantly delayed, indicating that CyP20 is involved in protein folding in the matrix. The slow folding in the mutant mitochondria was not inhibited by cyclosporin A. Folding intermediates of precursor molecules reversibly accumulated at the molecular chaperones Hsp70 and Hsp60 in the matrix. We conclude that CyP20 is a component of the mitochondrial protein folding machinery and that it cooperates with Hsp70 and Hsp60. It is speculated that peptidyl-prolyl cis-trans isomerases in other cellular compartments may similarly promote protein folding in cooperation with chaperone proteins.     

Functional independence of the protein translocation machineries in mitochondrial outer and inner membranes: passage of preproteins through the intermembrane space.

The protein translocation machineries of the outer and inner mitochondrial membranes usually act in concert during translocation of matrix and inner membrane proteins. We considered whether the two machineries can function independently of each other in a sequential reaction. Fusion proteins (pF-CCHL) were constructed which contained dual targeting information, one for the intermembrane space present in cytochrome c heme lyase (CCHL) and the other for the matrix space contained in the signal sequence of the precursor of F1-ATPase beta-subunit (pF1 beta). In the absence of a membrane potential, delta psi, the fusion proteins moved into the intermembrane space using the CCHL pathway. In contrast, in the presence of delta psi they followed the pF1 beta pathway and eventually were translocated into the matrix. The fusion protein pF51-CCHL containing 51 amino acids of pF1 beta, once transported into the intermembrane space in the absence of a membrane potential, could be further chased into the matrix upon re-establishing delta psi. The sequential and independent movement of the fusion protein across the two membranes demonstrates that the translocation machineries act as distinct entities. Our results support a model in which the two translocation machineries can function independently of each other, but generally interact in a dynamic fashion to achieve simultaneous translocation across both membranes. In addition, the results provide information about the targeting sequences within CCHL. The protein does not contain a signal for retention in the intermembrane space; rather, it lacks matrix targeting information, and therefore is unable to undergo delta psi-dependent interaction with the protein translocation apparatus in the inner membrane.