Mitochondrial processing proteinase: A general processing proteinase of spinach leaf mitochondria is a membrane-bound enzyme

Protein Processing in Plant Mitochondria Compared to Yeast and Mammals

Limited proteolysis, called protein processing, is an essential post-translational mechanism that controls protein localization, activity, and in consequence, function. This process is prevalent for mitochondrial proteins, mainly synthesized as precursor proteins with N-terminal sequences (presequences) that act as targeting signals and are removed upon import into the organelle. Mitochondria have a distinct and highly conserved proteolytic system that includes proteases with sole function in presequence processing and proteases, which show diverse mitochondrial functions with limited proteolysis as an additional one. In virtually all mitochondria, the primary processing of N-terminal signals is catalyzed by the well-characterized mitochondrial processing peptidase (MPP). Subsequently, a second proteolytic cleavage occurs, leading to more stabilized residues at the newly formed N-terminus. Lately, mitochondrial proteases, intermediate cleavage peptidase 55 (ICP55) and octapeptidyl protease 1 (OCT1), involved in proteolytic cleavage after MPP and their substrates have been described in the plant, yeast, and mammalian mitochondria. Mitochondrial proteins can also be processed by removing a peptide from their N- or C-terminus as a maturation step during insertion into the membrane or as a regulatory mechanism in maintaining their function. This type of limited proteolysis is characteristic for processing proteases, such as IMP and rhomboid proteases, or the general mitochondrial quality control proteases ATP23, m-AAA, i-AAA, and OMA1. Identification of processing protease substrates and defining their consensus cleavage motifs is now possible with the help of large-scale quantitative mass spectrometry-based N-terminomics, such as combined fractional diagonal chromatography (COFRADIC), charge-based fractional diagonal chromatography (ChaFRADIC), or terminal amine isotopic labeling of substrates (TAILS). This review summarizes the current knowledge on the characterization of mitochondrial processing peptidases and selected N-terminomics techniques used to uncover protease substrates in the plant, yeast, and mammalian mitochondria.

Proteolytic system of plant mitochondria

The existence of a proteolytic system which can specifically recognize and cleave proteins in mitochondria is now well established. The components of this system comprise processing peptidases, ATP-dependent peptidases and oligopeptidases. A short overview of experimentally confirmed proteases mainly from Arabidopsis thaliana is provided. The role of the mitochondrial peptidases in plant growth and development is emphasized. We also discuss the possibility of existence of as yet unidentified plant homologs of yeast mitochondrial ATP-independent proteases.

Processing peptidases in mitochondria and chloroplasts

Most of the mitochondrial and chloroplastic proteins are nuclear encoded and synthesized in the cytosol as precursor proteins with N-terminal extensions called targeting peptides. Targeting peptides function as organellar import signals, they are recognized by the import receptors and route precursors through the protein translocons across the organellar membranes. After the fulfilled function, targeting peptides are proteolytically cleaved off inside the organelles by different processing peptidases. The processing of mitochondrial precursors is catalyzed in the matrix by the Mitochondrial Processing Peptidase, MPP, the Mitochondrial Intermediate Peptidase, MIP (recently called Octapeptidyl aminopeptidase 1, Oct1) and the Intermediate cleaving peptidase of 55kDa, Icp55. Furthermore, different inner membrane peptidases (Inner Membrane Proteases, IMPs, Atp23, rhomboids and AAA proteases) catalyze additional processing functions, resulting in intra-mitochondrial sorting of proteins, the targeting to the intermembrane space or in the assembly of proteins into inner membrane complexes. Chloroplast targeting peptides are cleaved off in the stroma by the Stromal Processing Peptidase, SPP. If the protein is further translocated to the thylakoid lumen, an additional thylakoid-transfer sequence is removed by the Thylakoidal Processing Peptidase, TPP. Proper function of the D1 protein of Photosystem II reaction center requires its C-terminal processing by Carboxy-terminal processing protease, CtpA. Both in mitochondria and in chloroplasts, the cleaved targeting peptides are finally degraded by the Presequence Protease, PreP. The organellar proteases involved in precursor processing and targeting peptide degradation constitute themselves a quality control system ensuring the correct maturation and localization of proteins as well as assembly of protein complexes, contributing to sustenance of organelle functions. Dysfunctions of several mitochondrial processing proteases have been shown to be associated with human diseases. This article is part of a Special Issue entitled: Protein Import and Quality Control in Mitochondria and Plastids.

Biochemical and spectroscopic characterization of a novel metalloprotease, cotinifolin from an antiviral plant shrub: Euphorbia cotinifolia

A high molecular mass novel metalloprotease, cotinifolin is purified from the latex of Euphorbia cotinifolia by a combination of anion exchange and hydrophobic interaction chromatography. The nonglycosylated enzyme has a molecular mass of 79.76 kDa (ESI-MS) and the isoelectric point of the enzyme is pH 7.7. Cotinifolin hydrolyzes denatured natural substrates such as casein, azoalbumin, and hemoglobin with high specific activity. The K(m) value of the enzyme was found to be 20 μM with azocasein. The enzyme is not prone to autolysis even at very low concentrations. Polyclonal antibodies specific to enzyme was raised and immunodiffusion reveals that the enzyme has unique antigenic determinants. Maximum caseinolytic activity of cotinifolin is observed in the range of pH 7.0-8.0 and temperature of 50 °C. Using 0.2 mL of 1 mM solution of each metal ion, the purified protease was inhibited slightly by Ba²⁺ and Mn²⁺, moderately by Mg²⁺, Ca²⁺ and Cs²⁺ and significantly by Zn²⁺, Cu²⁺ and Co²⁺. On the other hand, substantial activation in caseinolytic activity was achieved by Ni²⁺. The enzyme activity was also inhibited by EDTA and o-phenanthroline but not by any other protease inhibitors. Perturbation studies by temperature, pH, and chaotrophs of the enzyme also reveal its high stability as seen by CD, fluorescence and proteolytic activity. Spectroscopic studies reveal that cotinifolin has secondary structural features with α/β type with approximately 9% of α-helicity. Easy availability and simple purification procedure makes the enzyme a good system for biophysical study, biotechnological and industrial applications.

Targeting capacity and conservation of PreP homologues localization in mitochondria of different species

Mitochondrial presequences and other unstructured peptides are degraded inside mitochondria by presequence proteases (PrePs) identified in Arabidopsis thaliana (AtPreP), humans (hPreP), and yeast (Cym1/Mop112). The presequences of A. thaliana and human PreP are predicted to consist of 85 and 29 amino acids, respectively, whereas the Saccharomyces cerevisiae Cym1/Mop112 presequence contains only 7 residues. These differences may explain the reported targeting of homologous proteins to different mitochondrial subcompartments. Here we have investigated the targeting capacity of the PreP homologues' presequences. We have produced fusion constructs containing N-terminal portions of AtPreP(1-125), hPreP(1-69), and Cym1(1-40) coupled to green fluorescent protein (GFP) and studied their import into isolated plant, mammalian, and yeast mitochondria, followed by mitochondrial subfractionation. Whereas the AtPreP presequence has the capacity to target GFP into the mitochondrial matrix of all three species, the hPreP presequence only targets GFP to the matrix of mammalian and yeast mitochondria. The Cym1/Mop112 presequence has an overall much weaker targeting capacity and only ensures mitochondrial sorting in its host species yeast. Revisiting the submitochondrial localization of Cym1 revealed that endogenous Cym1/Mop112 is localized to the matrix space, as has been previously reported for the plant and human homologues. Moreover, complementation studies in yeast show that native AtPreP restores the growth phenotype of yeast cells lacking Cym1, demonstrating functional conservation.

Processing of the dual targeted precursor protein of glutathione reductase in mitochondria and chloroplasts

Pea glutathione reductase (GR) is dually targeted to mitochondria and chloroplasts by means of an N-terminal signal peptide of 60 amino acid residues. After import, the signal peptide is cleaved off by the mitochondrial processing peptidase (MPP) in mitochondria and by the stromal processing peptidase (SPP) in chloroplasts. Here, we have investigated determinants for processing of the dual targeting signal peptide of GR by MPP and SPP to examine if there is separate or universal information recognised by both processing peptidases. Removal of 30 N-terminal amino acid residues of the signal peptide (GRDelta1-30) greatly stimulated processing activity by both MPP and SPP, whereas constructs with a deletion of an additional ten amino acid residues (GRDelta1-40) and deletion of 22 amino acid residues in the middle of the GR signal sequence (GRDelta30-52) could be cleaved by SPP but not by MPP. Numerous single mutations of amino acid residues in proximity of the cleavage site did not affect processing by SPP, whereas mutations within two amino acid residues on either side of the processing site had inhibitory effect on processing by MPP with a nearly complete inhibition for mutations at position -1. Mutation of positively charged residues in the C-terminal half of the GR targeting peptide inhibited processing by MPP but not by SPP. An inhibitory effect on SPP was detected only when double and triple mutations were introduced upstream of the cleavage site. These results indicate that: (i) recognition of processing site on a dual targeted GR precursor differs between MPP and SPP; (ii) the GR targeting signal has similar determinants for processing by MPP as signals targeting only to mitochondria; and (iii) processing by SPP shows a low level of sensitivity to single mutations on targeting peptide and likely involves recognition of the physiochemical properties of the sequence in the vicinity of cleavage rather than a requirement for specific amino acid residues.

NMR solution structure of the mitochondrial F1beta presequence from Nicotiana plumbaginifolia

We have isolated, characterized and determined the three-dimensional NMR solution structure of the presequence of ATPsynthase F1beta subunit from Nicotiana plumbaginifolia. A general method for purification of presequences is presented. The method is based on overexpression of a mutant precursor containing a methionine residue introduced at the processing site, followed by CNBr-cleavage and purification of the presequence on a cation-exchange column. The F1beta presequence, 53 amino acid residues long, retained its native properties as evidenced by inhibition of in vitro mitochondrial import and processing at micromolar concentrations. CD spectroscopy revealed that the F1beta presequence formed an alpha-helical structure in membrane mimetic environments such as SDS and DPC micelles (approximately 50% alpha-helix), and in acidic phospholipid bicelles (approximately 60% alpha-helix). The NMR solution structure of the F1beta presequence in SDS micelles was determined on the basis of 518 distance and 21 torsion angle constraints. The structure was found to contain two helices, an N-terminal amphipathic alpha-helix (residues 4-15) and a C-terminal alpha-helix (residues 43-53), separated by a largely unstructured 27 residue long internal domain. The N-terminal amphipathic alpha-helix forms the putative Tom20 receptor binding site, whereas the C-terminal alpha-helix is located upstream of the mitochondrial processing peptidase cleavage site.

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.

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.

Glycine-rich region of mitochondrial processing peptidase alpha-subunit is essential for binding and cleavage of the precursor proteins

Mitochondrial processing peptidase, a metalloendopeptidase consisting of alpha- and beta-subunits, specifically recognizes a large variety of mitochondrial precursor proteins and cleaves off amino-terminal extension peptides. The alpha-subunit has a characteristic glycine-rich segment in the middle portion. To elucidate the role of the region in processing functions of the enzyme, deletion or site-directed mutations were introduced, and effects on kinetic parameters and substrate binding of the enzyme were analyzed. Deletion of three residues of the region, Phe(289) to Ala(291), led to a dramatic reduction in processing activity to practically zero. Mutation of Phe(289), Lys(296), and Met(298) to alanine resulted in a decrease in the activity, but these mutations had no apparent effect on interactions between the two subunits, indicating that reduction in processing activity is not due to structural disruption at the interface interacting with the beta-subunit. Although the mutant enzymes, Phe289Ala, Lys296Ala, and Met298Ala, had an approximate 10-fold less affinity for substrate peptides than did that of the wild type, the deletion mutant, delta 289-291, showed an extremely low affinity. Thus, shortening of the glycine-rich stretch led to a dramatic reduction of interaction between the enzyme and substrate peptides and cleavage reaction, whereas mutation of each amino acid in this region seemed to affect primarily the cleavage reaction.

Mitochondrial processing peptidase: multiple-site recognition of precursor proteins

During or shortly after import of the precursor proteins into mitochondria, the amino-terminal extension peptides are first proteolytically removed by mitochondrial processing peptidase (MPP). The peptidase is a metalloendopeptidase, classified as a member of pitrilysin family, and forms a heterodimer consisting of structurally related alpha- and beta-subunits which are homologous to core proteins, core 2 and core 1, respectively, of mitochondrial ubiquinol-cytochrome c oxidoreductase complex. The enzyme specifically recognizes a large variety of mitochondrial precursor proteins and is cleaved at a single and specific site. In this review, I will focus on recognition mechanisms of precursor proteins by MPP. Structural characteristics of the precursor responsible for the recognition by MPP, role of each subunit, and amino acid residues of MPP involved in the recognition are discussed.

Glutamate residues required for substrate binding and cleavage activity in mitochondrial processing peptidase

Mitochondrial processing peptidase, a metalloendopeptidase consisting of alpha- and beta-subunits, specifically recognizes a large variety of mitochondrial precursor proteins and cleaves off N-terminal extension peptides. The enzyme requires the basic amino acid residues in the extension peptides for effective and specific cleavage. To elucidate the mechanism involved in the molecular recognition of substrate by the enzyme, several glutamates around the active site of the rat beta-subunit, which has a putative metal-binding motif, H56XXEH60, were mutated to alanines or aspartates, and effects on kinetic parameters, metal binding, and substrate binding of the enzyme were analyzed. None of mutant proteins analyzed was impaired in dimer formation with the alpha-subunit. Mutation of glutamates at positions 79, 129, and 136, in addition to an active-site glutamate at position 59, resulted in a marked decrease in cleavage efficiency. Together with sequence alignment data, glutamate 136 appears to be involved in metal binding. Glutamate 129 is mostly responsible for the catalysis, as there was a considerable decrease in kcat value by the mutation. Mutation of glutamate 79 led to decrease in kcat value and increase in Km values. Substrate binding experiments using an environmentally sensitive fluorescence probe attached to the peptide showed that the mutation caused a remarkable environmental change at the binding site to the N-terminal region of the substrate peptide and decreased binding of the peptide, thereby suggesting that glutamate 79 participates primarily in substrate binding. Thus, some glutamate residues required for substrate binding and cleavage activity have been identified.

Inhibition of protein import into mitochondria by amphiphilic cations: potential targets and mechanism of action

In this paper we describe for the first time the inhibitory effect of three amphiphilic cations, trifluoperazine, propranolol and dibucaine on mitochondrial protein import. The amphiphilic cations did not affect binding of mitochondrial precursor proteins to mitochondria. Import into mitoplasts was affected in a similar manner to intact mitochondria, indicating that the protein import machinery of the inner membrane of mitochondria was responsible for the observed effect. At concentrations which completely inhibited protein import, the amphiphilic cations did not affect the membrane potential (DeltaPsi) across the inner membrane. The inhibitory potency of amphiphilic cations reflects their lipid/water partition coefficient and relatively high concentrations of the drugs were required for complete inhibition, hence we propose that the mechanism of protein import inhibition by amphiphilic cations is due to membrane perturbing effects. We discuss the implications of our findings in view of the possible connection between various inner mitochondrial membrane channels and the protein import pore.

Role of alpha-subunit of mitochondrial processing peptidase in substrate recognition

Mitochondrial processing peptidase is a heterodimer consisting of alpha-mitochondrial processing peptidase (alpha-MPP) and beta-MPP. We investigated the role of alpha-MPP in substrate recognition using a recombinant yeast MPP. Disruption of amino acid residues between 10 and 129 of the alpha-MPP did not essentially impair binding activity with beta-MPP and processing activity, whereas truncation of the C-terminal 41 amino acids led to a significant loss of binding and processing activity. Several acidic amino acids in the region conserved among the enzymes from various species were mutated to asparagine or glutamine, and effects on processing of the precursors were analyzed. Glu353 is required for processing of malate dehydrogenase, aspartate aminotransferase, and adrenodoxin precursors. Glu377 and Asp378 are needed only for the processing of aspartate aminotransferase and adrenodoxin precursors, both of which have a longer extension peptide than the others studied. However, processing of the yeast alpha-MPP precursor, which has a short extension peptide of nine amino acids, was not affected by these mutations. Thus, effects of substitution of acidic amino acids on the processing differed with the precursor protein and depended on length of the extension peptides. alpha-MPP may function as a substrate-recognizing subunit by interacting mainly with basic amino acids at a region distal to the cleavage site in precursors with a longer extension peptide.

Activation of a matrix processing peptidase from the crystalline cytochrome bc1 complex of bovine heart mitochondria

No mitochondrial processing peptidase (MPP) activity is detected in crystalline bovine heart mitochondrial cytochrome bc1 complex, which possesses full electron transfer activity. However, when the complex is treated with increasing concentrations of Triton X-100 at 37 degreesC, the electron transfer activity decreases, whereas peptidase activity increases. Maximum MPP activity is obtained when the electron transfer activity in the complex is completely inactivated with 1.5 mM of Triton X-100. This result supports our suggestion that the lack of MPP activity in the mammalian cytochrome bc1 complex is because of binding of an inhibitor polypeptide to the active site of MPP located at the interface of core subunits I and II. This suggestion is based on the three-dimensional structural information for the bc1 complex and the sequence homology between subunits of MPP and the core subunits of the beef complex. Triton X-100, at concentrations that disrupt the structural integrity of the bc1 complex as indicated by the loss of its electron transfer activity, weakens the binding of inhibitor polypeptide to the active site of MPP in core subunits, thus activating MPP. The Triton X-100-activated MPP is pH-, buffer system-, ionic strength-, and temperature-dependent. Maximum activity is observed with an assay mixture containing 15 mM Tris-HCl buffer at neutral pH (6.5-8.5) and at 37 degreesC. Activated MPP is completely inhibited by metal ion chelators such as EDTA and o-phenanthroline and partially inhibited by myxothiazol (58%), ferricyanide (28%), and dithiothreitol (81%). The metal ion chelator-inhibited activity can be partially restored by the addition of divalent cations such as Zn2+ (68%), Mg2+ (44%), Mn2+ (54%), Co2+ (62%), and Fe2+ (92%), indicating that metal ion is required for MPP activity. The cleavage site specificity of activated MPP depends more on the length of amino acid sequence from the mature protein portion and less on the presequence portion, when a synthetic peptide composed of NH2-terminal residues of a mature protein and the COOH-terminal residues of its presequence is used as a substrate.

The mitochondrial processing peptidase behaves as a zinc-metallopeptidase

The yeast mitochondrial processing peptidase (MPP) and its subunits were purified in Escherichia coli under conditions for which the enzyme retains most of its processing activity in the absence of externally added divalent cation. The holoenzyme exhibited a Km value of 1.35 microM and a Vmax value of 0.25 microM/min and was inhibited by metal chelators in a time-dependent manner. Measurement of the metal content showed that both, MPP and beta-MPP, contained 0.86 and 1.05 atoms of Zn2+ per molecule, respectively. An enzymatically inactive MPP mutant carrying a mutation of the first histidine of the putative metal-ion binding HXXEH motif in beta-MPP retained less than 0.2 atom of Zn2+ per molecule. A metal-free enzyme (apoenzyme) was prepared from the holoenzyme and shown to be devoid of any processing activity. Incubation of the apoenzyme with 50 nM and 500 nM Zn2+ restored 50% and 80% of the processing activity, respectively. However, no reactivation occurred at concentrations of Zn2+ higher than 1 microM. Addition of 500 nM Mn2+ or higher concentrations (up to 50 microM) reactivated only 50% of the processing activity. The holoenzyme was competitively inhibited by molar excess of Zn2+ (Ki of 3.1 microM) but not by molar excess of Mn2+. Taken together, our data suggest that the authentic MPP is a Zn2+ rather than a Mn2+ metallopeptidase.

Functional cooperation of the mitochondrial processing peptidase subunits

Domains important for the activity of the heterodimeric mitochondrial processing peptidase (MPP) were investigated, by inserting one alanine residue at ten positions along the polypeptide chain of the beta-subunit (beta-MPP). An alanine residue inserted after Glu70, Ser114, Lys215 and Ser314 respectively, abolished the cleavage activity of MPP. When the alpha-subunit (alpha-MPP) was co-expressed with N-terminal hexa-histidine tagged beta-MPP, alpha-MPP was co-eluted from a nickel-derivatized affinity resin, with a 1:1 stochiometry, both with wild-type beta-MPP and with the mutants with alanine inserted after Ser114 and Ser314. The mutants with alanine inserted after Glu70 and Lys215 did not associate with alpha-MPP. The mutagenesis studies indicate that: (1) the whole HXXEHX76H region of beta-MPP is important for the proper conformation of the active site of MPP and may also be in contact with alpha-MPP; (2) the non-conserved central region surrounding Lys215 is involved in the interaction with alpha-MPP; and (3) the carboxy-terminal region of beta-MPP surrounding Ser314 is also of importance for the catalysis. Cross-linking studies indicated that purified alpha-MPP bound a precursor protein in the absence of any beta-MPP. Furthermore, the interaction of MPP and its subunits with a peptide substrate, as analyzed by surface plasmon resonance, showed that alpha-MPP bound a peptide substrate as efficiently as MPP. The data suggest that the alpha-subunit is responsible for the binding of mitochondrial presequences prior their presentation to the catalytic site of MPP.

The mitochondrial processing peptidase: function and specificity

Targeting signals of mitochondrial precursors are cleaved in the matrix during or after import by the mitochondrial processing peptidase (MPP). This enzyme consists of two nonidentical alpha- and beta-subunits each of molecular weight of about 50 kDa. In mammals and fungi, MPP is soluble in the matrix, whereas in plants the enzyme is part of the cytochrome bc1 complex. MPP is a metalloendopeptidase which has been classified as a member of the pitrilysin family on the basis of the HXXEHX76E zinc-binding motif present in beta-MPP. Both subunits of MPP are required for processing activity. The alpha-subunit of MPP, which probably recognizes a three-dimensional motif adopted by the presequence, presents the presequence to beta-MPP, which carries the catalytic active site. MPP acts as an endoprotease on chemically synthesized peptides corresponding to mitochondrial presequences. Matrix-targeting signals and MPP cleavage signals seem to be distinct, although the two signals may overlap within a given presequence. The structural element helix-turn-helix, that cleavable presequences adopt in a membrane mimetic environment, may be required for processing but is not sufficient for proteolysis. Binding of the presequence by alpha-MPP tolerates a high degree of mutations of the presequence. alpha-MPP may present a degenerated cleavage site motif to beta-MPP in an accessible conformation for processing. The conformation of mitochondrial presequences bound to MPP remains largely unknown.

Studies on protein processing for membrane-bound spinach leaf mitochondrial processing peptidase integrated into the cytochrome bc1 complex and the soluble rat liver matrix mitochondrial processing peptidase

The plant mitochondrial processing peptidase (MPP) that catalyses the cleavage of the presequences from precursor proteins during or after protein import is a membrane-bound enzyme that constitutes an integral part of the bc1 complex of the respiratory chain. In contrast, MPP from mammals is soluble in the matrix space and does not form part of the respiratory chain. In the present study, we have compared the substrate specificity of the isolated spinach leaf bc1/MPP with rat liver MPP using synthetic signal peptides and different mitochondrial precursor proteins. Inhibition studies of processing with synthetic peptides showed a similar inhibition pattern for plant and rat MPP activity. A peptide derived from the presequence of rat liver mitochondrial aldehyde dehydrogenase (ALDH) was a potent inhibitor of the spinach and rat MPP. Two nonprocessed signal peptides, rhodanese and linker-deleted ALDH (a form of ALDH that lacks the RGP linker connecting two helices in the presequence) had lower inhibitory effects towards each protease. The signal peptide from thiolase, another nonprocessed protein, had little inhibitory effect on MPP. Peptides derived from presequence of the plant Nicotiana plumbaginifolia F1 beta also showed a similar inhibitory pattern with rat MPP as with spinach MPP processing. In-vitro synthesised precursors of plant N. plumbaginifolia F1 beta and rat liver ALDH were cleaved to mature form by both spinach and rat MPP. However, the efficiency of processing was higher with the homologous precursor. Linker-deleted ALDH, rhodanese, and thiolase were not processed by the mammalian or plant MPP. However, both forms of MPP cleaved a mutated form of rhodanese that possesses a typical MPP cleavage motif, RXY S. Addition of the same cleavage motif to thiolase did not result in processing by either MPP. These results show that similar higher-order structural elements upstream from the cleavage site are important for processing by both the membrane-bound plant and the soluble mammalian MPP.

Evidence for a link between translocation and processing during protein import into soybean mitochondria

The effect of metal chelators on protein import was investigated using isolated soybean mitochondria and soybean precursor proteins. Adding 1,10-phenanthroline, a metal chelator that can cross both mitochondrial membranes abolished import of both the alternative oxidase, and the F(A)d subunit of the ATP synthase, a matrix located protein. Other metal chelators such as EDTA, 1,7-phenanthroline and 4,7-phenanthroline, which cannot cross the mitochondrial membranes, had no effect on import. When processing, a known metal-dependent step inside mitochondria, was inhibited using a mutagenesis approach (changing a -2 arginine to a -2 glycine in the pre-piece of the precursor), so was import. Thus it would appear that in soybean, at least, translocation of proteins across the mitochondrial membrane, as well as processing, relies on a metal dependent step. Taken together, the data suggest the two processes may be directly connected in these mitochondria.

Characterization of the bifunctional mitochondrial processing peptidase (MPP)/bc1 complex in Spinacia oleracea

The mitochondrial general processing peptidase (MPP) in plant mitochondria constitutes an integral part of the cytochrome bc1 complex of the respiratory chain. Here we present a characterization of this bifunctional complex from spinach leaf mitochondria. The purified MPP/bc1 complex has a molecular mass of 550 kDa, which corresponds to a dimer. Increased ionic strength results in partial dissociation of the dimer as well as loss of the processing activity. Micellar concentrations of nonionic and zwitterionic detergents stimulate the activity by decreasing the temperature optimum of the processing reaction, whereas anionic detergents totally suppress the activity. MPP is a metalloendopeptidase. Interestingly, hemin, a potent regulator of mitochondrial and cytosolic biogenesis and inhibitor of proteosomal degradation, inhibits the processing activity. Measurements of the processing activity at different redox states of the bc1 complex show that despite bifunctionality of the MPP/bc1 complex, there is no correlation between electron transfer and protein processing.

Functional analysis of a recently originating, atypical presequence: mitochondrial import and processing of GUS fusion proteins in transgenic tobacco and yeast

A gene family of at least five members encodes the tobacco mitochondrial Rieske Fe-S protein (RISP). To determine whether all five RISPs are translocated to mitochondria, fusion proteins containing the putative presequences of tobacco RISPs and Escherichia coli beta-glucuronidase (GUS) were expressed in transgenic tobacco, and the resultant GUS proteins were localized by cell fractionation. The amino-terminal 75 and 71 residues of RISP2 and RISP3, respectively, directed GUS import into mitochondria, where fusion protein processing occurred. The amino-terminal sequence of RISP4, which contains an atypical mitochondrial presequence, can translocate the GUS protein specifically into tobacco mitochondria with apparently low efficiency. Consistent with the proposal of a conserved mechanism for protein import in plants and fungi, the tobacco RISP3 and RISP4 presequences can direct import and processing of a GUS fusion protein in yeast mitochondria. Plant presequences, however, direct mitochondrial import in yeast less efficiently than the yeast presequence, indicating subtle differences between the plant and yeast mitochondrial import machineries. Our studies show that import of RISP4 may not require positively charged amino acid residues and an amphipathic secondary structure; however, these structural properties may improve the efficiency of mitochondrial import.

Plasma membrane-associated aminopeptidase activities in Chlamydomonas reinhardtii and their biochemical characterization

High aminopeptidase (Apase) activities were found on intact unicellular algae cells. Several lines of evidence strongly indicate that the external Apases on Chlamydomonas reinhardtii (a green alga) cells, characterized in the present study, are plasma membrane-associated proteinases and not secreted in the cell wall or the surrounding medium. This is shown by enzyme activities also detected on a cell wall deficient mutant of C. reinhardtii and by the finding that in assay media and algal conditioned nutrient solutions, respectively, no Apase activities were found after removal of cells. In C. reinhardtii at least two in vivo Apases, one L-leucine-p-nitroanilide and one L-alanine-p-nitroanilide hydrolyzing enzyme (in vivo LeuNAase and AlaNAase, respectively) as well as one in vivo endoproteinase, capable of cleaving carboxybenzoylleucine-p-nitroanilide (CBZLeuNAase), were clearly distinguished by their pH optima for activity and characteristics towards various chemical compounds. In vivo LeuNAase, which cannot unequivocally classified as a metallo- or serine-type proteinase, showed optimum activities between pH 7 and 8.5, stimulation of activity by 1,10-phenanthroline (161%), 2-fold higher activity with L-phenylalanine-p-nitroanilide than with LeuNA and a Km value of 40 microM LeuNA. In vivo AlaNAase favored alkaline pH values, had a Km value of 1.45 mM AlaNA and is probably a metallopeptidase as indicated by 2-fold enhancement of enzyme activity by 5 microM Co2+ and strong inhibition with 1,10-phenanthroline. This enzyme was inhibited completely by a 30 min incubation with 10 microM Hg2+ at room temperature, indicating sensitive SH-groups. In contrast, activity was stimulated 205% by 20 mM iodoacetate in the assay buffer. Both in vivo Apases were efficiently inhibited by 10 mM Pefabloc SC, a serine-type proteinase inhibitor and by two compounds, not yet described as proteinase inhibitors: methyljasmonate, a plant hormone, and dibucaine, a local anestheticum. The latter compound showed the most powerful inhibition on in vivo and in vitro LeuNAase of all reagents tested. From the distribution of Apase activities and characteristics in the cell, it is hypothesized that at least the LeuNAase dissociates easily from the plasma membrane during preparation of cell extracts and binds then unspecifically to various membrane fractions. In conclusion, this is the first report on the existence of external Apase activities on plant cells providing an easy-to-perform, rapid and reliable assay method for these enzymes.

Nucleo-mitochondrial interactions in mitochondrial gene expression

All proteins encoded by mitochondrial DNA (mtDNA) are dependent on proteins encoded by nuclear genes for their synthesis and function. Recent developments in the identification of these genes and the elucidation of the roles their products play at various stages of mitochondrial gene expression are covered in this review, which focuses mainly on work with the yeast Saccharomyces cerevisiae. The high degree of evolutionary conservation of many cellular processes between this yeast and higher eukaryotes, the ease with which mitochondrial biogenesis can be manipulated both genetically and physiologically, and the fact that it will be the first organism for which a complete genomic sequence will be available within the next 2 to 3 years makes it the organism of choice for drawing up an inventory of all nuclear genes involved in mitochondrial biogenesis and for the identification of their counterparts in other organisms.

The mitochondrial processing peptidase from potato: a self-processing enzyme encoded by two differentially expressed genes

Cytochrome c reductase from potato is a bifunctional protein complex located in the inner mitochondrial membrane, which is involved in respiratory electron transport and processing of mitochondrial precursor proteins. The three largest subunits of the complex share the highest degree of sequence identity with the alpha- and beta-subunits of the soluble processing peptidase (MPP) from fungi and mammals. Evidence is provided that another substoichiometric polypeptide of the cytochrome c reductase complex resembles the alpha-subunit of MPP. A cDNA clone corresponding to the second alpha-MPP protein (alpha-II MPP) encodes a polypeptide of 504 amino acids which is 84% identical to alpha-I MPP. The two different alpha-MPP polypeptides have similar sizes on SDS-polyacrylamide gels but can be distinguished with an antibody raised against a decapeptide that is specific for alpha-II MPP. The presequences of both alpha-subunits of MPP are proteolytically removed by the integrated processing enzyme complex indicating that it acts on the targeting signals of its own precursor proteins. Gene-specific oligonucleotides reveal that the genes encoding alpha-subunit I and alpha-subunit II of MPP are differentially expressed in all tissues analysed but the transcript levels do not vary between tissues.

Tissue-specific differences of the mitochondrial protein import machinery: in vitro import, processing and degradation of the pre-F1 beta subunit of the ATP synthase in spinach leaf and root mitochondria

In this study we report the first comparison of the mitochondrial protein import and processing events in two different tissues from the same organism. Both spinach leaf and root mitochondria were able to import and process the in vitro transcribed and translated Neurospora crassa F1 beta subunit of ATP synthase to the mature size product. Temperature optimum for protein import, 20 degrees C, was considerably lower than that found in other systems. In spinach leaf mitochondria, the processing peptidase has been shown to constitute an integral part of the bc1 complex of the respiratory chain. In accordance with these results, the majority of the processing activity in root mitochondria was also localized in the membrane. However, although the same amount of the processing peptidase was present per mg of membrane protein in both leaf and root mitochondria, as determined immunologically, the specific processing activity was several-fold higher in roots. Furthermore, in contrast to the processing enzyme in leaf, a portion of the processing activity could be disassociated from the root membrane with relatively weak salt treatment. The processing event in both the leaf and root membranes was always accompanied by a degradation of the F1 beta precursor. The degradation activity was found to be several-fold higher in roots than in leaves and was also partially dissociated from the membrane after salt treatment. Both the processing and degradation activities were inhibited by orthophenanthroline, a known metalloprotease inhibitor. These results show tissue-specific differences of the processing event catalyzed by the bc1 complex and indicate the presence of two populations of the processing peptidase in root mitochondria.

Bifunctional role of the bc1 complex in plants. Mitochondrial bc1 complex catalyses both electron transport and protein processing

Nuclear encoded mitochondrial precursor proteins are cleaved to mature size products by the general mitochondrial processing peptidase (MPP). In contrast to non-plant sources where MPP is a matrix enzyme, the plant mitochondrial MPP is localised in the inner membrane and constitutes an integral part of the bc1 complex of the respiratory chain. Core proteins of the complex are immunologically related and show high sequence similarity to the MPP subunits from non-plant sources. The bc1 complex in plants is thus bifunctional, being involved both in respiration and in protein processing.

Efficient but aberrant cleavage of mitochondrial precursor proteins by the chloroplast stromal processing peptidase

Cytosol-synthesized chloroplast and mitochondrial precursor proteins are proteolytically processed after import by highly specific, metal-dependent soluble enzymes: the stromal processing peptidase (SPP) and the matrix processing peptidase (MPP), respectively. We have used in vitro processing assays to compare the reaction specificities of highly purified preparations of pea SPP and Neurospora crassa MPP, both of which are unable to cleave a variety of 'foreign' proteins. We show that SPP can cleave all five mitochondrial precursor proteins tested, namely cyclophilin, the beta subunit of the F1-ATPase complex, the Rieske FeS protein, the alpha-MPP subunit and cytochrome b2. In contrast, MPP is unable to cleave any chloroplast precursor proteins tested. Several of the mitochondrial precursor proteins are cleaved more efficiently by SPP than are many authentic chloroplast precursor proteins but, in each case, cleavage takes place at a site or sites which are N-terminal to the authentic MPP site; pre-cyclophilin is cleaved 5 residues upstream of the MPP site and the precursor of the beta subunit of the F1-ATPase complex is cleaved at sites 5 and 12 residues upstream. We discuss the implications of these data for the SPP reaction mechanism.