Mitochondrial protein import: identification of processing peptidase and of PEP, a processing enhancing protein

Transport of nuclear-encoded precursor proteins into mitochondria includes proteolytic cleavage of amino-terminal targeting sequences in the mitochondrial matrix. We have isolated the processing activity from Neurospora crassa. The final preparation (enriched ca. 10,000-fold over cell extracts) consists of two proteins, the matrix processing peptidase (MPP, 57 kd) and a processing enhancing protein (PEP, 52 kd). The two components were isolated as monomers. PEP is about 15-fold more abundant in mitochondria than MPP. It is partly associated with the inner membrane, while MPP is soluble in the matrix. MPP alone has a low processing activity whereas PEP alone has no apparent activity. Upon recombining both, full processing activity is restored. Our data indicate that MPP contains the catalytic site and that PEP has an enhancing function. The mitochondrial processing enzyme appears to represent a new type of "signal peptidase," different from the bacterial leader peptidase and the signal peptidase of the endoplasmic reticulum.     

Matrix processing peptidase of mitochondria. Structure-function relationships

The mitochondrial processing peptidase (MPP) and the processing enhancing protein (PEP) cooperate in the proteolytic cleavage of matrix targeting sequences from nuclear-encoded mitochondrial precursor proteins. We have determined the cDNA sequence of Neurospora MPP after expression cloning. MPP appears to contain two domains of approximately equal size which are separated by a loop-like sequence. Considerable structural similarity exists to the recently sequenced yeast MPP as well as to Neurospora and yeast PEP. Four cysteine residues are conserved in Neurospora and yeast MPP. Inactivation of MPP can be achieved by using sulfhydryl reagents. MPP (but not PEP) depends on the presence of divalent metal ions for activity. Both MPP and PEP are synthesized as precursors containing matrix targeting signals which are processed during import into mitochondria by the mature forms of MPP and PEP.     

Complementation between mitochondrial processing peptidase (MPP) subunits from different species.

Mitochondrial processing peptidase (MPP), a dimer of nonidentical subunits, is the primary peptidase responsible for the removal of leader peptides from nuclearly encoded mitochondrial proteins. Alignments of the alpha and beta subunits of MPP (alpha- and beta-MPP) from different species show strong protein sequence similarity in certain regions, including a highly negatively charged region as well as a domain containing a putative metal ion binding site. In this report, we describe experiments in which we combine the subunits of MPP from yeast, rat, and Neurospora crassa, both in vivo and in vitro and mesure the resultant processing activity. For in vivo complementation, we used the temperature sensitive mif1 and mif2 yeast mutants, which lack MPP activity at the nonpermissive temperature (37 degrees C). We found that the defective alpha-MPP of mif2 cannot be substituted for by the alpha-MPP from rat or Neurospora. On the other hand, the beta-MPP from rat and Neurospora can fully substitute for the defective beta-MPP in the mif1 mutant. These results were confirmed in in vitro experiments in which individually expressed subunits were combined. Only combinations of the alpha-MPP from yeast with the beta-MPP from rat or Neurospora produced active MPP.     

Timing and structural consideration for the processing of mitochondrial matrix space proteins by the mitochondrial processing peptidase (MPP)

Most mitochondrial matrix space proteins are synthesized as a precursor protein, and the N-terminal extension of amino acids that served as the leader sequence is removed after import by the action of a metalloprotease called mitochondrial processing peptidase (MPP). The crystal structure of MPP has been solved very recently, and it has been shown that synthetic leader peptides bind with MPP in an extended conformation. However, it is not known how MPP recognizes hundreds of leader peptides with different primary and secondary structures or when during import the leader is removed. Here we took advantage of the fact that the structure of the leader from rat liver aldehyde dehydrogenase has been determined by 2D-NMR to possess two helical portions separated by a three amino acid (RGP) linker. When the linker was deleted, the leader formed one long continuous helix that can target a protein to the matrix space but is not removed by the action of MPP. Repeats of two and three leaders were fused to the precursor protein to determine the stage of import at which processing occurs, if MPP could function as an endo peptidase, and if it would process if the cleavage site was part of a helix. Native or linker deleted constructs were used. Import into isolated yeast mitochondria or processing with recombinantly expressed MPP was performed. It was concluded that processing did not occur as the precursor was just entering the matrix space, but most likely coincided with the folding of the protein. Further, finding that hydrolysis could not take place if the processing site was part of a stable helix is consistent with the crystal structure of MPP. Lastly, it was found that MPP could function at sites as far as 108 residues from the N terminus of the precursor protein, but its ability to process decreases exponentially as the distance increases.     

Molecular identification of the ten subunits of cytochrome-c reductase from potato mitochondria

Cytochrome-c reductase (EC 1.10.2.2.) from Solanum tuberosum L. comprises ten subunits with apparent molecular sizes of 55, 53, 51, 35, 33, 25, 14, 12, 11 and 10 kDa on 14% SDS-PAGE. The identity of the subunits was analysed by direct amino-acid sequencing via cyclic Edman degradation. A large-scale purification procedure for the enzyme complex based on affinity chromatography and gelfiltraton is described. All subunits were enzymatically fragmented and the generated peptides were separated by reverse-phase HPLC. Complete or partial sequence determination of 33 peptides comprising a total of nearly 500 amino acids showed, that cytochrome-c reductase from potato contains three respiratory proteins (cytochrome b, cytochrome c ₁ and the Rieske iron-sulfur protein), four small proteins with molecular sizes below 15 kDa (so-called Q-binding, hinge, cytochrome-c ₁-linked and core-linked proteins) and three proteins in the 50-kDa range which show similarity to members of the core/PEP/MPP protein family (core/processing enhancing protein/mitochondrial processing peptidase). In fact these subunits show highest sequence identity either to MPP or PEP, which is in line with earlier findings, that isolated cytochrome-c reductase from potato exhibits processing activity towards mitochondrial precursor proteins.Abbreviations MPP mitochondrial processing peptidase - PEP processing enhancing protein This research was supported by the Deutsche Forschungsgemeinschaft.     

A Highlights from MBoC Selection: More than just a ticket canceller: the mitochondrial processing peptidase tailors complex precursor proteins at internal cleavage sites

Most mitochondrial proteins are synthesized as precursors that carry N-terminal presequences. After they are imported into mitochondria, these targeting signals are cleaved off by the mitochondrial processing peptidase (MPP). Using the mitochondrial tandem protein Arg5,6 as a model substrate, we demonstrate that MPP has an additional role in preprotein maturation, beyond the removal of presequences. Arg5,6 is synthesized as a polyprotein precursor that is imported into mitochondria and subsequently separated into two distinct enzymes. This internal processing is performed by MPP, which cleaves the Arg5,6 precursor at its N-terminus and at an internal site. The peculiar organization of Arg5,6 is conserved across fungi and reflects the polycistronic arginine operon in prokaryotes. MPP cleavage sites are also present in other mitochondrial fusion proteins from fungi, plants, and animals. Hence, besides its role as a “ticket canceller” for removal of presequences, MPP exhibits a second conserved activity as an internal processing peptidase for complex mitochondrial precursor proteins.     

Core I protein of bovine ubiquinol-cytochrome-c reductase; an additional member of the mitochondrial-protein-processing family. Cloning of bovine core I and core II cDNAs and primary structure of the proteins.

Core I and core II proteins are the largest nuclear-encoded subunits of the mitochondrial ubiquinol-cytochrome-c reductase (bc1 complex) lacking redox prosthetic groups. cDNA clones of the two bovine core proteins have been isolated by the screening of lambda ZAP cDNA libraries either with an oligonucleotide probe based on the sequence of an internal peptide or with a polymerase-chain-reaction-amplified fragment. The core I precursor protein consists of 362 amino acids with a 34-amino-acid presequence typical for mitochondrial targeting signals. The mature protein migrates in SDS/polyacrylamide gels with an apparent molecular mass of 47 kDa, which does not correspond to the actual molecular mass of the protein of 35.8 kDa deduced from the cDNA sequence. The core II precursor protein is composed of 453 amino acids having a 14-amino-acid presequence as a targeting sequence. Comparison of the core I amino acid sequence with sequences of the newly discovered protein family [Schulte, U., Arretz, M., Schneider, H., Tropschug, M., Wachter E., Neupert, W. & Weiss, H. (1989) Nature 339, 147 - 149] comprising the processing enhancing protein (PEP), matrix processing peptidase (MPP), and core I and II proteins from Neurospora crassa and Saccharomyces cerevisiae, revealed a remarkable identity of 39% and a high similarity of 49% to N. crassa PEP, which in this fungus is identical to core I. Core II protein is only a distant relative of this protein family. Based on these sequence comparisons and data obtained by genomic Southern blots, we anticipate that the bovine core I subunit, like the N. crassa core I protein, is bifunctional, being responsible for the maintenance of electron transport and processing of proteins during their import into the mitochondrial matrix. The analysis of the primary structure of the two core proteins completes the set of primary structures of all subunits of bovine ubiquinol-cytochrome-c reductase.     

A matrix-located processing peptidase of plant mitochondria

Nuclear-encoded mitochondrial precursor proteins are proteolytically processed inside the mitochondrion after import. The general mitochondrial processing activity in plant mitochondria has been shown to be integrated into the cytochrome bc₁ complex of the respiratory chain. Here we investigate the occurrence of an additional, matrix-located processing activity by incubation of the precursors of the soybean mitochondrial proteins, alternative oxidase, the F_Ad subunit of the ATP synthetase and the tobacco F₁ subunit of the ATP synthase, with the membrane and soluble components of mitochondria isolated from soybean cotyledons and spinach leaves. A matrix-located peptidase specifically processed the precursors to the predicted mature form in a reaction which was sensitive to orthophenanthroline, a characteristic inhibitor of mitochondrial processing peptidase (MPP). The specificity of the matrix peptidase was illustrated by the inhibition of processing of the alternative oxidase precursor in both soybean and spinach matrix extracts upon altering a single amino acid residue in the targeting presequence (-2 Arg to Gly). Additionally, there was no evidence for general proteolysis of precursor proteins incubated with the matrix. The purity of the matrix fractions was ascertained by spectrophotometric and immunological analyses. The results demonstrate that there is a specific processing activity in the matrix of soybean and spinach in addition to the previously well characterized membrane-bound MPP integrated into the cytochrome bc₁ complex of the respiratory chain.     

Mitochondrial protein turnover: role of the precursor intermediate peptidase Oct1 in protein stabilization

Most mitochondrial proteins are encoded in the nucleus as precursor proteins and carry N-terminal presequences for import into the organelle. The vast majority of presequences are proteolytically removed by the mitochondrial processing peptidase (MPP) localized in the matrix. A subset of precursors with a characteristic amino acid motif is additionally processed by the mitochondrial intermediate peptidase (MIP) octapeptidyl aminopeptidase 1 (Oct1), which removes an octapeptide from the N-terminus of the precursor intermediate. However, the function of this second cleavage step is elusive. In this paper, we report the identification of a novel Oct1 substrate protein with an unusual cleavage motif. Inspection of the Oct1 substrates revealed that the N-termini of the intermediates typically carry a destabilizing amino acid residue according to the N-end rule of protein degradation, whereas mature proteins carry stabilizing N-terminal residues. We compared the stability of intermediate and mature forms of Oct1 substrate proteins in organello and in vivo and found that Oct1 cleavage increases the half-life of its substrate proteins, most likely by removing destabilizing amino acids at the intermediate's N-terminus. Thus Oct1 converts unstable precursor intermediates generated by MPP into stable mature proteins.     

Yeast and human frataxin are processed to mature form in two sequential steps by the mitochondrial processing peptidase.

Frataxin is a nuclear-encoded mitochondrial protein which is deficient in Friedreich's ataxia, a hereditary neurodegenerative disease. Yeast mutants lacking the yeast frataxin homologue (Yfh1p) show iron accumulation in mitochondria and increased sensitivity to oxidative stress, suggesting that frataxin plays a critical role in mitochondrial iron homeostasis and free radical toxicity. Both Yfh1p and frataxin are synthesized as larger precursor molecules that, upon import into mitochondria, are subject to two proteolytic cleavages, yielding an intermediate and a mature size form. A recent study found that recombinant rat mitochondrial processing peptidase (MPP) cleaves the mouse frataxin precursor to the intermediate but not the mature form (Koutnikova, H., Campuzano, V., and Koenig, M. (1998) Hum. Mol. Gen. 7, 1485-1489), suggesting that a different peptidase might be required for production of mature size frataxin. However, in the present study we show that MPP is solely responsible for maturation of yeast and human frataxin. MPP first cleaves the precursor to intermediate form and subsequently converts the intermediate to mature size protein. In this way, MPP could influence frataxin function and indirectly affect mitochondrial iron homeostasis.     

Mitochondrial processing peptidases

Three peptidases are responsible for the proteolytic processing of both nuclearly and mitochondrially encoded precursor polypeptides targeted to the various subcompartments of the mitochondria. Mitochondrial processing peptidase (MPP) cleaves the vast majority of mitochondrial proteins, while inner membrane peptidase (IMP) and mitochondrial intermediate peptidase (MIP) process specific subsets of precursor polypeptides. All three enzymes are structurally and functionally conserved across species, and their human homologues begin to be recognized as potential players in mitochondrial disease.     

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.     

Glu(191) and Asp(195) in rat mitochondrial processing peptidase beta subunit are involved in effective cleavage of precursor protein through interaction with the proximal arginine

Mitochondrial processing peptidase (MPP), consisting of alpha and beta subunits, recognizes a large variety of N-terminal extension peptides of mitochondrial precursor proteins, and generally cleaves a single site of the peptide including arginine at the -2 position (P(2)). We obtained evidence that Glu(191) and Asp(195) of rat beta subunit interact with P(2) arginine of precursor protein through ionic and hydrogen bonds, respectively, using recombinant MPP. Mutation to alanines at Glu(191) and Asp(195) reduced processing activity toward precursors with P(2) arginine, but resulted in no loss of activity toward P(2) alanine precursors. Charge-complementary mutation demonstrated that MPP variants with beta Arg(191) exhibited compensatory processing activity for the precursor with acidic residue at the P(2) position. Thus, Glu(191) and Asp(195) are substrate-binding sites required for cleavage of extension peptides through interaction with P(2) arginine.     

Reconstitution of mitochondrial processing peptidase from the core proteins (subunits I and II) of bovine heart mitochondrial cytochrome bc(1) complex

Mature core I and core II proteins of the bovine heart mitochondrial cytochrome bc(1) complex were individually overexpressed in Escherichia coli as soluble proteins using the expression vector pET-I and pET-II, respectively. Purified recombinant core I and core II alone show no mitochondrial processing peptidase (MPP) activity. When these two proteins are mixed together, MPP activity is observed. Maximum activity is obtained when the molar ratio of these two core proteins reaches 1. This indicates that only the two core subunits of thebc(1) complex are needed for MPP activity. The properties of reconstituted MPP are similar to those of Triton X-100-activated MPP in the bovine bc(1) complex. When Rieske iron-sulfur protein precursor is used as substrate for reconstituted MPP, the processing activity stops when the amount of product formation (subunit IX) equals the amount of reconstituted MPP used in the system. Addition of Triton X-100 to the product-inhibited reaction mixture restores MPP activity, indicating that Triton X-100 dissociates bound subunit IX from the active site of reconstituted MPP. The aromatic group, rather than the hydroxyl group, at Tyr(57) of core I is essential for reconstitutive activity.     

Two related genes encoding extremely hydrophobic proteins suppress a lethal mutation in the yeast mitochondrial processing enhancing protein.

The processing enhancing protein of mitochondria (PEP) is an essential component that has been shown to participate in proteolytic removal of NH2-terminal signal peptides from precursor proteins imported into the mitochondrial matrix. Using a yeast strain bearing a PEP mutation that renders it temperature-sensitive, an approach of genetic suppression was taken in order to identify additional components that could be involved with protein import: high copy plasmids comprising a yeast genomic library were tested for ability to suppress the 37 degrees C growth defect. Two plasmids were isolated, pSMF1 and pSMF2, which suppressed the growth defect nearly as well as the cloned PEP gene itself. Sequence analysis of the rescuing genes predicted extremely hydrophobic proteins with sizes of 63 and 60 kDa, respectively. Remarkably, the predicted SMF1 and SMF2 products are 49% identical to each other overall. To test the requirement for SMF1 and SMF2, the chromosomal genes were disrupted. Individual disruption was without effect, but cells in which both genes were disrupted grew poorly. When mitochondria were prepared from the double disruption strain grown in a nonfermentable carbon source, they were morphologically normal but defective for translocation of radiolabeled precursor proteins. SMF1 protein was provisionally localized to the mitochondrial membranes using epitope tagging. We suggest that SMF1 and SMF2 are mitochondrial membrane proteins that influence PEP-dependent protein import, possibly at the step of protein translocation.     

Amino-terminal octapeptides function as recognition signals for the mitochondrial intermediate peptidase.

We have shown previously that cleavage of a number of precursors by the mitochondrial processing peptidase (MPP) requires an intermediate octapeptide (FXXSXXXX) between the MPP cleavage site and the mature protein amino terminus. We show now that these octapeptides, present at the amino termini of the intermediates, direct recognition of these substrates by the mitochondrial intermediate peptidase (MIP), leading to formation of mature proteins. Synthetic peptides, corresponding to the intermediate octapeptides of human ornithine transcarbamylase (OTC) and of Neurospora cytochrome c reductase Fe/S subunit (Fe/S), inhibit the processing activity of purified rat liver MIP in vitro, without affecting MPP activity; this indicates that the octapeptides can be recognized by MIP independent of the presence of the corresponding mature proteins and interact with a site that is crucial for MIP activity. MIP activity is not inhibited by a peptide lacking the amino-terminal hydrophobic residue, while substitution of such a residue by a polar amino acid causes a 10-fold reduction in the efficiency of MIP inhibition. To analyze the requirements for removal of the octapeptide from the intermediate proteins by MIP, artificial intermediates were synthesized and subjected to in vitro processing by purified MIP. The octapeptide can be cleaved by MIP only when the amino-terminal hydrophobic residue is also the amino terminus of the intermediate. Further, when the OTC octapeptide is joined to the mature amino terminus of another twice-cleaved precursor (pFe/S; rat malate dehydrogenase, pMDH), the chimeric intermediate is cleaved by MIP to the corresponding mature-sized protein. When the OTC octapeptide is joined to the mature amino terminus of a once-cleaved precursor (yeast F1-beta-ATPase, pF1-beta), however, this intermediate is not cleaved by MIP; rather, it is processed by MPP to mature-sized F1-beta. Therefore, amino-terminal octapeptides can be cleaved by MIP only within the structural context of twice-cleaved precursors.     

Rat liver mitochondrial intermediate peptidase (MIP): purification and initial characterization.

A number of nuclearly encoded mitochondrial protein precursors that are transported into the matrix and inner membrane are cleaved in two sequential steps by two distinct matrix peptidases, mitochondrial processing peptidase (MPP) and mitochondrial intermediate peptidase (MIP). We have isolated and purified MIP from rat liver mitochondrial matrix. The enzyme, purified 2250-fold, is a monomer of 75 kDa and cleaves all tested mitochondrial intermediate proteins to their mature forms. About 20% of the final MIP preparation consists of equimolar amounts of two peptides of 47 kDa and 28 kDa, which are apparently the products of a single cleavage of the 75 kDa protein. These peptides are not separable from the 75 kDa protein, nor from each other, under any conditions used in the purification. The peptidase has a broad pH optimum between pH 6.6 and 8.9 and is inactivated by N-ethylmaleimide (NEM) and other sulfhydryl group reagents. The processing activity is divalent cation-dependent; it is stimulated by manganese, magnesium or calcium ions and reversibly inhibited by EDTA. Zinc, cobalt and iron strongly inhibit MIP activity. This pattern of cation dependence and inhibition is not clearly consistent with that of any known family of proteases.     

Eukaryotic precursor proteins are processed by Escherichia coli outer membrane protein OmpP.

A new specific endopeptidase that cleaves eukaryotic precursor proteins has been found in Escherichia coli K but not in E. coli B strains. After purification, protein sequencing and Western blotting, the endopeptidase was shown to be identical with E. coli outer membrane protein OmpP [Kaufmann, A., Stierhof, Y.-D. & Henning, U. (1994) J. Bacteriol. 176, 359-367]. Further characterization of enzymatic properties of the new peptidase was performed. Comparison of the cleavage specificities of the newly found endopeptidase and that of rat mitochondrial processing peptidase (MPP) showed that patterns of proteolytic cleavage on the investigated precursor proteins by both enzymes are similar. By using three mitochondrial precursor proteins, the specificity assigned to OmpP previously, a cleavage position between two basic amino-acid residues, was extended to a three amino-acid recognition sequence. Positions +1 to +3 of this extended recognition site consist of an amino-acid residue with a small aliphatic side chain such as alanine or serine, a large hydrophobic residue such as leucine or valine followed by an arginine residue. Additionally, structural motifs of the substrate seem to be required for OmpP cleavage.     

A functionally divergent hydrogenosomal peptidase with protomitochondrial ancestry

Matrix proteins of mitochondria, hydrogenosomes and mitosomes are typically targeted and translocated into their respective organelles using N-terminal presequences that are subsequently cleaved by a peptidase. Here we characterize a approximately 47 kDa metallopeptidase, from the hydrogenosome-bearing, unicellular eukaryote Trichomonas vaginalis, that contains the active site motif (HXXEHX(76)E) characteristic of the beta subunit of the mitochondrial processing peptidase (MPP) and localizes to hydrogenosomes. The purified recombinant protein, named hydrogenosomal processing peptidase (HPP), is capable of cleaving a hydrogenosomal presequence in vitro, in contrast to MPP which requires both an alpha and beta subunit for activity. T. vaginalis HPP forms an approximately 100 kDa homodimer in vitro and also exists in an approximately 100 kDa complex in vivo. Our phylogenetic analyses support a common origin for HPP and betaMPP and demonstrate that gene duplication gave rise to alphaMPP and betaMPP before the divergence of T. vaginalis and mitochondria-bearing lineages. These data, together with published analyses of MPPs and putative mitosomal processing peptidases, lead us to propose that the length of targeting presequences and the subunit composition of organellar processing peptidases evolved in concert. Specifically, longer mitochondrial presequences may have evolved to require an alpha/beta heterodimer for accurate cleavage, while shorter hydrogenosomal and mitosomal presequences did not.