The sorting signal of cytochrome b2 promotes early divergence from the general mitochondrial import pathway and restricts the unfoldase activity of matrix Hsp70.

Cytochrome b2 is imported into mitochondria and sorted to the intermembrane space by a bipartite N-terminal presequence, which is a matrix targeting sequenced followed by an intermembrane space sorting signal. The N-terminus of the mature protein forms a folded heme binding domain that depends on the unfoldase function of matrix (mt) Hsp70 for import. We report that the distance between the presequence and the heme binding domain is critical for the ability of mt-Hsp70 to promote import of the domain. Hybrid proteins with 40 or more amino acids between the presequence and the heme binding domain are arrested in the import machinery. The translocation arrest can be overcome by unfolding of the preprotein or by inactivation of the intermembrane space sorting signal. Moreover, the sorting signal prevents backsliding of the precursor polypeptide in the import site in the initial import step, when the signal has not made contact with the matrix. The results indicate that the sorting signal interacts with component(s) of the inner membrane/intermembrane space during the initial import step and promotes an early divergence of b2 preproteins from the general matrix import pathway, precluding an unfolding role for mt-Hsp70 in the translocation of most of the mature portions of a preprotein. We propose a sorting model of cytochrome b2 which explains the apparently divergent previous results by a unifying hypothesis.     

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.     

Mitochondrial protein import: biochemical and genetic evidence for interaction of matrix hsp70 and the inner membrane protein MIM44

The import of preproteins into mitochondria involves translocation of the polypeptide chains through putative channels in the outer and inner membranes. Preprotein-binding proteins are needed to drive the unidirectional translocation of the precursor polypeptides. Two of these preprotein-binding proteins are the peripheral inner membrane protein MIM44 and the matrix heat shock protein hsp70. We report here that MIM44 is mainly exposed on the matrix side, and a fraction of mt- hsp70 is reversibly bound to the inner membrane. Mt-hsp70 binds to MIM44 in a 1:1 ratio, suggesting that mt-hsp70 is localizing to the membrane via its interaction with MIM44. Formation of the complex requires a functional ATPase domain of mt-hsp70. Addition of Mg-ATP leads to dissociation of the complex. Overexpression of mt-hsp70 rescues the protein import defect of mutants in MIM44; conversely, overexpression of MIM44 rescues protein import defects of mt-hsp70 mutants. In addition, yeast strains with conditional mutations in both MIM44 and mt-hsp70 are barely viable, showing a synthetic growth defect compared to strains carrying single mutations. We propose that MIM44 and mt-hsp70 cooperate in translocation of preproteins. By binding to MIM44, mt-hsp70 is recruited at the protein import sites of the inner membrane, and preproteins arriving at MIM44 may be directly handed over to mt-hsp70.     

Mitochondrial GrpE is present in a complex with hsp70 and preproteins in transit across membranes.

We characterized a 24-kDa protein associated with matrix hsp70 (mt-hsp70) of Neurospora crassa and Saccharomyces cerevisiae mitochondria. By using specific antibodies, the protein was identified as MGE, a mitochondrial homolog of the prokaryotic heat shock protein GrpE. MGE extracted from mitochondria was quantitatively bound to hsp70. It was efficiently released from hsp70 by the addition of Mg-ATP but not by nonhydrolyzable ATP analogs or high salt. A mutant mt-hsp70, which was impaired in release of bound precursor proteins, released MGE in an ATP-dependent manner, indicating that precursor proteins and MGE bind to different sites of hsp70. A preprotein accumulated in transit across the mitochondrial membranes was specifically coprecipitated by either antibodies directed against MGE or antibodies directed against mt-hsp70. The preprotein accumulated at the outer membrane was not coprecipitated by either antibody preparation. After being imported into the matrix, the preprotein could be coprecipitated only by antibodies against mt-hsp70. We propose that mt-hsp70 and MGE cooperate in membrane translocation of preproteins.     

Structural basis for the function of Tim50 in the mitochondrial presequence translocase

Many mitochondrial proteins are synthesized as preproteins carrying amino-terminal presequences in the cytosol. The preproteins are imported by the translocase of the outer mitochondrial membrane and the presequence translocase of the inner membrane. Tim50 and Tim23 transfer preproteins through the intermembrane space to the inner membrane. We report the crystal structure of the intermembrane space domain of yeast Tim50 to 1.83 Å resolution. A protruding β-hairpin of Tim50 is crucial for interaction with Tim23, providing a molecular basis for the cooperation of Tim50 and Tim23 in preprotein translocation to the protein-conducting channel of the mitochondrial inner membrane.     

Studies on the topology of the protein import channel in relation to the plant mitochondrial processing peptidase integrated into the cytochrome bc1 complex

The mitochondrial processing peptidase (MPP) specifically cleaves N-terminal targeting signals from hundreds of nuclear-encoded, matrix-targeted precursor proteins. In contrast to yeast and mammals, the plant MPP is an integral component of the respiratory cytochrome bc1 complex. The topology of the protein import channel in relation to MPP/bc1 in plants was studied using chimeric precursors containing truncated cytochrome b2 (cyt b2) proteins of 55-167 residues in length, fused to dihydrofolate reductase (DHFR). The DHFR domain could be tightly folded by methotrexate (MTX), generating translocation intermediates trapped in the import channel with only the cyt b2 pre-sequence/mature domain protruding into the matrix. Spinach and soybean mitochondria imported and processed unfolded precursors. MTX-folded intermediates were not processed in spinach but the longest (1-167) MTX-folded cyt b2-DHFR construct was processed in soybean, while yeast mitochondria successfully processed even shorter MTX-folded constructs. The MTX-folded precursors were cleaved with high efficiency by purified spinach MPP/bc1 complex. We interpret these results as indicating that the protein import channel is located distantly from the MPP/bc1 complex in plants, and that there is no link between protein translocation and protein processing.     

Role of the chaperonin cofactor Hsp10 in protein folding and sorting in yeast mitochondria

Protein folding in mitochondria is mediated by the chaperonin Hsp60, the homologue of E. coli GroEL. Mitochondria also contain a homologue of the cochaperonin GroES, called Hsp10, which is a functional regulator of the chaperonin. To define the in vivo role of the co- chaperonin, we have used the genetic and biochemical potential of the yeast S. cerevisiae. The HSP10 gene was cloned and sequenced and temperature-sensitive lethal hsp10 mutants were generated. Our results identify Hsp10 as an essential component of the mitochondrial protein folding apparatus, participating in various aspects of Hsp60 function. Hsp10 is required for the folding and assembly of proteins imported into the matrix compartment, and is involved in the sorting of certain proteins, such as the Rieske Fe/S protein, passing through the matrix en route to the intermembrane space. The folding of the precursor of cytosolic dihydrofolate reductase (DHFR), imported into mitochondria as a fusion protein, is apparently independent of Hsp10 function consistent with observations made for the chaperonin-mediated folding of DHFR in vitro. The temperature-sensitive mutations in Hsp10 map to a domain (residues 25-40) that corresponds to a previously identified mobile loop region of bacterial GroES and result in a reduced binding affinity of hsp10 for the chaperonin at the non-permissive temperature.     

Differential requirement for the mitochondrial Hsp70-Tim44 complex in unfolding and translocation of preproteins.

The mitochondrial heat shock protein Hsp70 is essential for import of nuclear-encoded proteins, involved in both unfolding and membrane translocation of preproteins. mtHsp70 interacts reversibly with Tim44 of the mitochondrial inner membrane, yet the role of this interaction is unknown. We analysed this role by using two yeast mutants of mtHsp70 that differentially influenced its interaction with Tim44. One mutant mtHsp70 (Ssc1-2p) efficiently bound preproteins, but did not show a detectable complex formation with Tim44; the mitochondria imported loosely folded preproteins with wild-type kinetics, yet were impaired in unfolding of preproteins. The other mutant Hsp70 (Ssc1-3p') bound both Tim44 and preproteins, but the mitochondria did not import folded polypeptides and were impaired in import of unfolded preproteins; Ssc1-3p' was defective in its ATPase domain and did not undergo a nucleotide-dependent conformational change, resulting in permanent binding to Tim44. The following conclusions are suggested. (i) The import of loosely folded polypeptides (translocase function of mtHsp70) does not depend on formation of a detectable Hsp70-Tim44 complex. Two explanations are possible: a trapping mechanism by soluble mtHsp70, or a weak/very transient interaction of Ssc1-2p with Tim44 that leads to a weak force generation sufficient for import of loosely folded, but not folded, polypeptides. (ii) Import of folded preproteins (unfoldase function of mtHsp70) involves a reversible nucleotide-dependent interaction of mtHsp70 with Tim44, including a conformational change in mtHsp70. This is consistent with a model that the dynamic interaction of mtHsp70 with Tim44 generates a pulling force on preproteins which supports unfolding during translocation.     

Precursor proteins in transit through mitochondrial contact sites interact with hsp70 in the matrix

We previously reported that hsp70 in the mitochondrial matrix (mt-hsp 70 = Ssclp) is required for import of precursor proteins destined for the matrix or intermembrane space. Here we show that mt-hsp70 is also needed for the import of mitochondrial inner membrane proteins. In particular, the precursor of ADP/ATP carrier that is known not to interact with hsp60 on its assembly pathway requires functional mt-hsp70 for import, suggesting a general role of mt-hsp70 in membrane translocation of precursors. Moreover, a precursor arrested in contact sites was specifically co-precipitated with antibodies directed against mt-hsp70. We conclude that mt-hsp70 is directly involved in the translocation of many, if not all, precursor proteins that are transported across the inner membrane.     

Hsp78, a Clp homologue within mitochondria, can substitute for chaperone functions of mt-hsp70.

Hsp78 is a Clp homologue within mitochondria of Saccharomyces cerevisiae. Deletion of HSP78 does not cause any detectable changes in wild type cells, but results in a petite phenotype in the ssc1-3 mutant strain carrying a temperature-sensitive allele of mt-hsp70. When overexpressed in the ssc1-3 mutant strain, hsp78 suppresses the defect in mitochondrial protein import under permissive conditions in vitro and interacts directly with newly imported polypeptide chains. As a molecular chaperone, hsp78 prevents the aggregation of misfolded proteins in the matrix of mitochondria under conditions of impaired mt-hsp70 function. However, unlike misfolded proteins associated with mt-hsp70, hsp78-bound polypeptides are not efficiently degraded by the ATP-dependent PIM1 protease. Thus, hsp78 can partially substitute for mt-hsp70 functions in the assembly of mitochondria and may be part of a salvage pathway if mt-hsp70 is limiting.     

A novel intermediate on the import pathway of cytochrome b2 into mitochondria: evidence for conservative sorting.

Cytochrome b2 is sorted into the intermembrane space of mitochondria by a bipartite N-terminal targeting and sorting presequence. In an attempt to define the sorting pathway we have identified an as yet unknown import intermediate. Cytochrome b2-dihydrofolate reductase (DHFR) fusion proteins were arrested in the presence of methotrexate (MTX) so that the DHFR domain was at the surface of the outer membrane while the N-terminus reached into the intermembrane space where the sorting signal was removed. This membrane-spanning, mature-sized species was efficiently chased into the mitochondria upon removal of MTX. Thus, an intermediate was generated which was exposed to the intermembrane space but was still associated with the inner membrane. This intermediate was also found upon direct import of cytochrome b2 and derived fusion proteins. These membrane-bound mature-sized cytochrome b2 species loop through the matrix and could be recovered in a complex with mt-Hsp70 and the inner membrane MIM44/ISP45, a component of the inner membrane import apparatus. This novel sorting intermediate can only be explained by a pathway in which cytochrome b2 passes through the matrix. The existence of such an intermediate is inconsistent with a pathway by which entrance of the mature part of cytochrome b2 into the matrix is stopped by the sorting sequence; however, its presence is fully consistent with the conservative sorting pathway.     

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.     

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.     

Preprotein transport machineries of yeast mitochondrial outer membrane are not required for Bax-induced release of intermembrane space proteins

The mitochondrial outer membrane contains protein import machineries, the translocase of the outer membrane (TOM) and the sorting and assembly machinery (SAM). It has been speculated that TOM or SAM are required for Bax-induced release of intermembrane space (IMS) proteins; however, experimental evidence has been scarce. We used isolated yeast mitochondria as a model system and report that Bax promoted an efficient release of soluble IMS proteins while preproteins were still imported, excluding an unspecific damage of mitochondria. Removal of import receptors by protease treatment did not inhibit the release of IMS proteins by Bax. Yeast mutants of each Tom receptor and the Tom40 channel were not impaired in Bax-induced protein release. We analyzed a large collection of mutants of mitochondrial outer membrane proteins, including SAM, fusion and fission components, but none of these components was required for Bax-induced protein release. The released proteins included complexes up to a size of 230 kDa. We conclude that Bax promotes efficient release of IMS proteins through the outer membrane of yeast mitochondria while the inner membrane remains intact. Inactivation of the known protein import and sorting machineries of the outer membrane does not impair the function of Bax at the mitochondria.     

Protein import into mitochondria of Neurospora crassa

Biogenesis of mitochondria requires import of several hundreds of different nuclear-encoded preproteins needed for mitochondrial structure and function. Import and sorting of these preproteins is a multistep process facilitated by complex proteinaceous machineries located in the mitochondrial outer and inner membranes. The translocase of the mitochondrial outer membrane, the TOM complex, comprises receptors which specifically recognize mitochondrial preproteins and a protein conducting channel formed by TOM40. The TOM complex is able to insert resident proteins into the outer membrane and to translocate proteins into the intermembrane space. For import of inner membrane or matrix proteins, the TOM complex cooperates with translocases of the inner membrane, the TIM complexes. During the past 30 years, intense research on fungi enabled the identification and mechanistic characterization of a number of different proteins involved in protein translocation. This review focuses on the contributions of the filamentous fungus Neurospora crassa to our current understanding of mitochondrial protein import, with special emphasis on the structure and function of the TOM complex.     

The signal that sorts yeast cytochrome b2 to the mitochondrial intermembrane space contains three distinct functional regions.

Cytochrome b2, a protein of the yeast mitochondrial intermembrane space, is synthesized with an 80 residue bipartite presequence. The amino-terminal portion resembles a matrix-targeting signal. The carboxy-terminal portion acts as a 'sorting signal' for the intermembrane space and contains a hydrophobic stretch. In order to define this sorting signal, we fused the first 167 residues of the cytochrome b2 precursor to a passenger protein, expressed the fusion protein in yeast and selected for mutations that caused mislocalization of the passenger protein to the matrix. Most mutations mapped within the first 81 amino-terminal residues of the cytochrome b2 moiety. They were located in three regions, all downstream of the matrix-targeting domain: a cluster of three basic residues upstream of the hydrophobic stretch, the hydrophobic stretch itself and the first residue of mature cytochrome b2. The level of missorting caused by mutations within the hydrophobic stretch did not correlate with their effects on hydrophobicity, but appeared to be related to changes in the conformation of this stretch. We conclude that the intermembrane space sorting signal of cytochrome b2 is decoded by protein-protein interactions rather than by simple partitioning into a lipid bilayer.     

Targeting of cytochrome b2 into the mitochondrial intermembrane space: specific recognition of the sorting signal.

Cytochrome b2 contains 2-fold targeting information: an amino-terminal signal for targeting to the mitochondrial matrix, followed by a second cleavable sorting signal that functions in directing the precursor into the mitochondrial intermembrane space. The role of the second sorting sequence was analyzed by replacing one, two or all of the three positively charged amino acid residues which are present at the amino-terminal side of the hydrophobic core by uncharged residues or an acidic residue. With a number of these mutant precursor proteins, processing to the mature form was reduced or completely abolished and at the same time targeting to the matrix space occurred. The accumulation in the matrix depended on a high level of intramitochondrial ATP. At low levels of matrix ATP, the mutant proteins were sorted into the intermembrane space like the wild-type precursors. The results: (i) suggest the existence of one or more matrix components that specifically recognize the second sorting signal and thereby trigger the translocation into the intermembrane space; (ii) indicate that the mutant signals have reduced ability to interact with the recognition component(s) and then embark on the default pathway into the matrix by interacting with mitochondrial hsp70 in conjunction with matrix ATP; (iii) strongly argue against a mechanism by which the hydrophobic segment of the sorting sequence stops translocation in the hydrophobic phase of the inner membrane.     

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.     

Mechanisms of protein translocation into mitochondria.

Mitochondrial biogenesis utilizes a complex proteinaceous machinery for the import of cytosolically synthesized preproteins. At least three large multisubunit protein complexes, one in the outer membrane and two in the inner membrane, have been identified. These translocase complexes cooperate with soluble proteins from the cytosol, the intermembrane space and the matrix. The translocation of presequence-containing preproteins through the outer membrane channel includes successive electrostatic interactions of the charged mitochondrial targeting sequence with a chain of import components. Translocation across the inner mitochondrial membrane utilizes the energy of the proton motive force of the inner membrane and the hydrolysis of ATP. The matrix chaperone system of the mitochondrial heat shock protein 70 forms an ATP-dependent import motor by interaction with the polypeptide chain in transit and components of the inner membrane translocase. The precursors of integral inner membrane proteins of the metabolite carrier family interact with newly identified import components of the intermembrane space and are inserted into the inner membrane by a second translocase complex. A comparison of the full set of import components between the yeast Sacccharomyces cerevisiae and the nematode Caenorhabditis elegans demonstrates an evolutionary conservation of most components of the mitochondrial import machinery with a possible greater divergence for the import pathway of the inner membrane carrier proteins.     

Mitochondria use different mechanisms for transport of multispanning membrane proteins through the intermembrane space

The mitochondrial inner membrane contains numerous multispanning integral proteins. The precursors of these hydrophobic proteins are synthesized in the cytosol and therefore have to cross the mitochondrial outer membrane and intermembrane space to reach the inner membrane. While the import pathways of noncleavable multispanning proteins, such as the metabolite carriers, have been characterized in detail by the generation of translocation intermediates, little is known about the mechanism by which cleavable preproteins of multispanning proteins, such as Oxa1, are transferred from the outer membrane to the inner membrane. We have identified a translocation intermediate of the Oxa1 preprotein in the translocase of the outer membrane (TOM) and found that there are differences from the import mechanisms of carrier proteins. The intermembrane space domain of the receptor Tom22 supports the stabilization of the Oxa1 intermediate. Transfer of the Oxa1 preprotein to the inner membrane is not affected by inactivation of the soluble TIM complexes. Both the inner membrane potential and matrix heat shock protein 70 are essential to release the preprotein from the TOM complex, suggesting a close functional cooperation of the TOM complex and the presequence translocase of the inner membrane. We conclude that mitochondria employ different mechanisms for translocation of multispanning proteins across the aqueous intermembrane space.