Targeting and translocation of proteins into the hydrogenosome of the protist Trichomonas: similarities with mitochondrial protein import.

Trichomonads are early-diverging eukaryotes that lack both mitochondria and peroxisomes. They do contain a double membrane-bound organelle, called the hydrogenosome, that metabolizes pyruvate and produces ATP. To address the origin and biological nature of hydrogenosomes, we have established an in vitro protein import assay. Using purified hydrogenosomes and radiolabeled hydrogenosomal precursor ferredoxin (pFd), we demonstrate that protein import requires intact organelles, ATP and N-ethylmaleimide-sensitive cytosolic factors. Protein import is also affected by high concentrations of the protonophore, m-chlorophenylhydrazone (CCCP). Binding and translocation of pFd into hydrogenosomes requires the presence of an eight amino acid N-terminal presequence that is similar to presequences found on all examined hydrogenosomal proteins. Upon import, pFd is processed to a size consistent with cleavage of the presequence. Mutation of a conserved leucine at position 2 in the presequence to a glycine disrupts import of pFd into the organelle. Interestingly, a comparison of hydrogenosomal and mitochondrial protein presequences reveals striking similarities. These data indicate that mechanisms underlying protein targeting and biogenesis of hydrogenosomes and mitochondria are similar, consistent with the notion that these two organelles arose from a common endosymbiont.     

Sequence homologies between glyoxysomal and mitochondrial malate dehydrogenase

The comparison of mitochondrial and glyoxysomal malate dehydrogenase (EC 1.1.1.37) from cotyledons of germinating watermelon (Citrullus vulgaris Schrad., cv. Kleckey's Sweet No. 6) by means of serological methods and peptide patterns revealed a high degree of homology. The N-terminal sequence analysis yielded a distinct presequence of eight or nine amino-acid residues, respectively, which is followed by an almost identical stretch of at least 20 amino-acid residues. A very similar domain has been recognized for mitochondrial malate dehydrogenase from porcine heart and yeast, and for Escherichia coli malate dehydrogenase.Abbreviations gMDH glyoxysomal malate dehydrogenase - mMDH mitochondrial malate dehydrogenase - SDS sodium dodecyl sulfate     

Functions of outer membrane receptors in mitochondrial protein import

Most mitochondrial proteins are synthesized in the cytosol as precursor proteins and are imported into mitochondria. The targeting signals for mitochondria are encoded in the presequences or in the mature parts of the precursor proteins, and are decoded by the receptor sites in the translocator complex in the mitochondrial outer membrane. The recently determined NMR structure of the general import receptor Tom20 in a complex with a presequence peptide reveals that, although the amphiphilicity and positive charges of the presequence is essential for the import ability of the presequence, Tom20 recognizes only the amphiphilicity, but not the positive charges. This leads to a new model that different features associated with the mitochondrial targeting sequence of the precursor protein can be recognized by the mitochondrial protein import system in different steps during the import.     

Glyoxysomal and mitochondrial malate dehydrogenase of watermelon (Citrullus vulgaris) cotyledons

Molecular properties of the glyoxysomal and mitochondrial isoenzyme of malate dehydrogenase (EC 1.1.1.37; L-malate: NAD⁺ oxidoreductase) from watermelon cotyledons (Citrullus vulgaris Schrad.) were investigated, using completely purified enzyme preparations. The apparent molecular weights of the glyoxysomal and mitochondrial isoenzymes were found to be 67,000 and 74,000 respectively. Aggregation at high enzyme concentrations was observed with the glyoxysomal but not with the mitochondrial isoenzyme. Using sodium dodecyl sulfate electrophoresis each isoenzyme was found to be composed of two polypeptide chains of identical size (33,500 and 37,000, respectively). The isoenzymes differed in their isoelectric points (gMDH: 8,92, mMDH: 5.39), rate of heat inactivation (gMDH: _1/2 at 40°C=3.0 min; mMDH: stable at 40°C; _1/2 at 60°C=4.5 min), adsorption to dextran gels at low ionic strenght, stability against alkaline conditions and their pH optima for oxaloacetate reduction (gMDH: pH 6.6, mMDH: pH 7.5). Very similar pH optima, however, were observed for L-malate oxidation (pH 9.3–9.5). The results indicate that the glyoxysomal and mitochondrial MDH of watermelon cotyledons are distinct proteins of different structural composition.Abbreviations EDTA ethylene diamine tetraacetic acid - gMDH and mMDH glyoxysomal and mitochondrial malate dehydrogenase, respectively     

Roles of Tom70 in Import of Presequence-containing Mitochondrial Proteins

Mitochondrial protein traffic requires precise recognition of the mitochondrial targeting signals by the import receptors on the mitochondrial surface including a general import receptor Tom20 and a receptor for presequence-less proteins, Tom70. Here we took a proteome-wide approach of mitochondrial protein import in vitro to find a set of presequence-containing precursor proteins for recognition by Tom70. The presequences of the Tom70-dependent precursor proteins were recognized by Tom20, whereas their mature parts exhibited Tom70-dependent import when attached to the presequence of Tom70-independent precursor proteins. The mature parts of the Tom70-dependent precursor proteins have the propensity to aggregate, and the presence of the receptor domain of Tom70 prevents their aggregate formation. Therefore Tom70 plays the role of a docking site for not only cytosolic chaperones but also aggregate-prone substrates to maintain their solubility for efficient transfer to downstream components of the mitochondrial import machineries.     

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 -glucuronidase (GUS) were expressed in transgenic tobacco, and the resultant GUS proteins were localized by cell fractionation. The aminoterminal 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.     

A cysteine endopeptidase with a C-terminal KDEL motif isolated from castor bean endosperm is a marker enzyme for the ricinosome, a putative lytic compartment

A papain-type cysteine endopeptidase with a molecular mass of 35 kDa for the mature enzyme, was purified from germinating castor bean (Ricinus communis L.) endosperm by virtue of its capacity to process the glyoxysomal malate dehydrogenase precursor protein to the mature subunit in vitro (C. Gietl et al., 1997, Plant Physiol 113: 863–871). The cDNA clones from endosperm of germinating seedlings and from developing seeds were isolated and sequence analysis revealed that a very similar or identical peptidase is synthesised in both tissues. Sequencing established a presequence for co-translational targeting into the endoplasmic reticulum, an N-terminal propeptide and a C-terminal KDEL motif for the castor bean cysteine endopeptidase precursor. The 45-kDa pro-enzyme stably present in isolated organelles was enzymatically active. Immunocytochemistry with antibodies raised against the purified cysteine endopeptidase revealed highly specific labelling of ricinosomes, organelles which co-purify with glyoxysomes from germinating Ricinus endosperm. The cysteine endopeptidase from castor bean endosperm, which represents a senescing tissue, is homologous to cysteine endopeptidases from other senescing tissues such as the cotyledons of germinating mung bean (Vigna mungo) and vetch (Vicia sativa), the seed pods of maturing French bean (Phaseolus vulgaris) and the flowers of daylily (Hemerocallis sp.). Received: 20 December 1997 / Accepted: 18 March 1998     

Biogenesis of eel liver citrate carrier (CIC): negative charges can substitute for positive charges in the presequence

A family of structurally related carrier proteins mediates the flux of metabolites across the mitochondrial inner membrane. Differently from most other mitochondrial proteins, members of the carrier family are synthesized without an amino-terminal targeting sequence. However, in some mammalian and plant species, representatives were identified that carry a positively charged presequence. To obtain data on a carrier protein from lower vertebrates, we determined the primary structure of eel mitochondrial citrate carrier (CIC) and investigated its import pathway into the target organelle. The protein carries a cleavable presequence of 20 amino acids, including two positively charged residues. The cleavage site is recognized by a magnesium-dependent peptidase in the intermembrane space. The presequence is dispensable both for targeting and translocation, but prior to import into mitochondria, significantly increases the solubility of the precursor protein. This effect is completely retained if the positive charges are exchanged with negative charges. Following this observation, we found that several carrier proteins appear to carry non-cleavable presequences that may similarly act as charged intramolecular chaperones.     

Investigations on the in vitro import ability of mitochondrial precursor proteins synthesized in wheat germ transcription-translation extract

Mitochondrial precursor proteins synthesized in rabbit reticulocyte lysate (RRL) are readily imported into mitochondria, whereas the same precursors synthesized in wheat germ extract (WGE) fail to be imported. We have investigated factors that render import incompetence from WGE. A precursor that does not require addition of extramitochondrial ATP for import, the F(A)d ATP synthase subunit, is imported from WGE. Import of chimeric constructs between precursors of the F(A)d protein and alternative oxidase (AOX) with switched presequences revealed that the mature domain of the F(A)d precursor defines the import competence in WGE as only the construct containing the presequence of AOX and mature portion of F(A)d (pAOX-mF(A)d) could be imported. Import competence of F(A)d and pAOX-mF(A)d correlated with solubility of these precursors in WGE, however, solubilization of import-incompetent precursors with urea did not restore import competence. Addition of RRL to WGE-synthesized precursors did not stimulate import but addition of WGE to the RRL-synthesized precursors or to the over-expressed mitochondrial precursor derived from the F1beta ATP synthase precursor inhibited import into mitochondria. The dual-targeted glutathione reductase precursor synthesized in WGE was imported into chloroplasts, but not into mitochondria. Antibodies against the 14-3-3 guidance complex characterized for chloroplast targeting were able to immunoprecipitate all of the precursors tested except the F(A)d ATP synthase precursor. Our results point to the conclusion that the import incompetence of WGE-synthesized mitochondrial precursors is not presequence dependent and is a result of interaction of WGE inhibitory factors with the mature portion of precursor proteins.     

Import of glyoxysomal malate dehydrogenase precursor into glyoxysomes: A heterologous in-vitro system

A heterologous in-vitro system is described for the import of the precursor to glyoxysomal malate dehydrogenase from watermelon (Citrullus vulgaris Schrad., cv. Kleckey's Sweet No. 6) cotyledons into glyoxysomes from castor-bean (Ricinus communis L.) endosperm. The 41-kDa precursor is posttranslationally sequestered and correctly processed to the mature 33-kDa subunit by a crude glyoxysomal fraction or by glyoxysomes purified on a sucrose gradient. The import and the cleavage of the extrasequence is not inhibited by metal chelators such as 1,10-phenanthroline and ethylenediaminetetraacetic acid. Uncouplers (carbonylcyanide m-chlorophenylhydrazone), ionophores (valinomycin), or inhibitors of oxidative phosphorylation (oligomycin) and ATP-ADP translocation (carboxyatractyloside) do not interfere, thus indicating the independence of the process of import by the organelle from the energization of the glyoxysomal membrane.Abbreviations CCCP carbonylcyanide m-chlorophenylhydrazone - EDTA ethylenediaminetetraacctic acid - gMDH glyoxysomal malate dehydrogenase - PMSF phenylmethylsulfonyl fluoride     

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.     

A cysteine endopeptidase isolated from castor bean endosperm microbodies processes the glyoxysomal malate dehydrogenase precursor protein.

A plant cysteine endopeptidase with a molecular mass of 35 kD was purified from microbodies of germinating castor bean (Ricinus communis) endosperm by virtue of its capacity to specifically process the glyoxysomal malate dehydrogenase precursor protein to the mature subunit in vitro. Processing of the glyoxysomal malate dehydrogenase precursor occurs sequentially in three steps, the first intermediate resulting from cleavage after arginine-13 within the presequence and the second from cleavage after arginine-33. The endopeptidase is unable to remove the presequences of prethiolases from rape (Brassica napus) glyoxysomes and rat peroxisomes at the expected cleavage site. Protein sequence analysis of N-terminal and internal peptides revealed high identity to the mature papain-type cysteine endopeptidases from cotyledons of germinating mung bean (Vigna mungo) and French bean (Phaseolus vulgaris) seeds. These endopeptidases are synthesized with an extended pre-/prosequence at the N terminus and have been considered to be processed in the endoplasmic reticulum and targeted to protein-storing vacuoles.     

Glyoxysomal malate dehydrogenase of watermelon cotyledons: De novo synthesis on cytoplasmic ribosomes

The development of glyoxysomal malate dehydrogenase (gMDH, EC 1.1.1.37) during early germination of watermelon seedlings (Citrullus vulgaris Schrad.) was determined in the cotyledons by means of radial immunodiffusion. The active isoenzyme was found to be absent in dry seeds. By density labelling with deuterium oxide and incorporation of [¹⁴C] amino acids it was shown that the marked increase of gMDH activity in the cotyledons during the first 4 days of germination was due to de novo synthesis of the isoenzyme. The effects of protein synthesis inhibitors (cycloheximide and chloramphenicol) on the synthesis of gMDH indicated that the glyoxysomal isoenzyme was synthesized on cytoplasmic ribosomes. Possible mechanisms by which the glyoxysomal malate dehydrogenase isoenzyme reaches its final location in the cell are discussed.Abbreviations mMDH mitochondrial malate dehydrogenase - gMDH glyoxysomal malate dehydrogenase - D₂O deuterium oxide - EDTA ethylenediaminetetraacetic acid, disodium salt     

Transport of proteins into yeast mitochondria

The amino-terminal sequences of several imported mitochondrial precursor proteins have been shown to contain all the information required for transport to and sorting within mitochondria. Proteins transported into the matrix contain a matrix-targeting sequence. Proteins destined for other submitochondrial compartments contain, in addition, an intramitochondrial sorting sequence. The sorting sequence in the cytochrome c1 presequence is a stop-transport sequence for the inner mitochondrial membrane. Proteins containing cleavable presequences can reach the intermembrane space by either of two pathways: (1) Part of the presequence is transported into the matrix; the attached protein, however, is transported across the outer but not the inner membrane (eg, the cytochrome c1 presequence). (2) The precursor is first transported into the matrix; part of the presequence is then removed, and the protein is reexported across the inner membrane (eg, the precursor of the iron-sulphur protein of the cytochrome bc1 complex). Matrix-targeting sequences lack primary amino acid sequence homology, but they share structural characteristics. Many DNA sequences in a genome can potentially encode a matrix-targeting sequence. These sequences become active if positioned upstream of a protein coding sequence. Artificial matrix-targeting sequences include synthetic presequences consisting of only a few different amino acids, a known amphiphilic helix found inside a cytosolic protein, and the presequence of an imported chloroplast protein. Transport of proteins across mitochrondrial membranes requires a membrane potential, ATP, and a 45-kd protein of the mitochondrial outer membrane. The ATP requirement for import is correlated with a stable structure in the imported precursor molecule. We suggest that transmembrane transport of a stably folded precursor requires an ATP-dependent unfolding of the precursor protein.     

Refining the Definition of Plant Mitochondrial Presequences through Analysis of Sorting Signals,N-Terminal Modifications,and Cleavage Motifs

Mitochondrial protein import is a complex multistep process from synthesis of proteins in the cytosol, recognition by receptors on the organelle surface, to translocation across one or both mitochondrial membranes and assembly after removal of the targeting signal, referred to as a presequence. In plants, import has to further discriminate between mitochondria and chloroplasts. In this study, we determined the precise cleavage sites in the presequences for Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa) mitochondrial proteins using mass spectrometry by comparing the precursor sequences with experimental evidence of the amino-terminal peptide from mature proteins. We validated this method by assessments of false-positive rates and comparisons with previous available data using Edman degradation. In total, the cleavable presequences of 62 proteins from Arabidopsis and 52 proteins from rice mitochondria were determined. None of these proteins contained amino-terminal acetylation, in contrast to recent findings for chloroplast stromal proteins. Furthermore, the classical matrix glutamate dehydrogenase was detected with intact and amino-terminal acetylated sequences, indicating that it is imported into mitochondria without a cleavable targeting signal. Arabidopsis and rice mitochondrial presequences had similar isoelectric points, hydrophobicity, and the predicted ability to form an amphiphilic α-helix at the amino-terminal region of the presequence, but variations in length, amino acid composition, and cleavage motifs for mitochondrial processing peptidase were observed. A combination of lower hydrophobicity and start point of the amino-terminal α-helix in mitochondrial presequences in both Arabidopsis and rice distinguished them (98%) from Arabidopsis chloroplast stroma transit peptides. Both Arabidopsis and rice mitochondrial cleavage sites could be grouped into three classes, with conserved −3R (class II) and −2R (class I) or without any conserved (class III) arginines. Class II was dominant in both Arabidopsis and rice (55%–58%), but in rice sequences there was much less frequently a phenylalanine (F) in the −1 position of the cleavage site than in Arabidopsis sequences. Our data also suggest a novel cleavage motif of (F/Y)↓(S/A) in plant class III sequences.Plant mitochondria play a key role in energy production and metabolism that requires the import and assembly of at least 1,000 proteins. Protein import into mitochondria begins with synthesis of the precursor protein in the cytosol, followed by binding to various proteins in the cytosol, binding to receptors on the outer mitochondrial membrane, translocation across one or both mitochondrial membranes, removal of the targeting signal, termed a presequence, and intraorganellar sorting and assembly. A variety of studies have shown that there is no primary amino acid sequence conservation among presequences, but they do have a high proportion of positively charged residues and the capacity to form an amphiphilic α-helix (Roise et al., 1986; von Heijne, 1986). Many mitochondrial presequences have a loosely conserved motif near the cleavage site comprising an Arg residue at the −2 and/or −3 position (von Heijne et al., 1989; Schneider et al., 1998). This Arg has been experimentally shown to be an important recognition site for the mitochondrial processing peptidase (MPP; Arretz et al., 1994; Ogishima et al., 1995; Tanudji et al., 1999). MPP is a heterodimeric enzyme that contains two similar subunits: α-MPP is involved in binding precursor proteins and β-MPP catalyzes the cleavage of the presequence (Kitada et al., 1995; Luciano et al., 1997). In yeast and mammals, MPP is a soluble protein located in the matrix, but in plants, MPP is integrated into the inner membrane-bound cytochrome b/c₁ complex (Braun et al., 1992; Eriksson et al., 1994; Glaser and Dessi, 1999).The mechanism through which the targeting signal binds to a receptor protein has been revealed by NMR studies and the crystal structure of rat Tom20 (for translocase of the outer membrane) with a bound presequence (Abe et al., 2000; Saitoh et al., 2007). A dynamic binding model in which different hydrophobic residues in the presequence interact with Tom20 has been proposed. Thus, the presequence has mobility in the binding site via hydrophobic interactions, with several different binding states being possible. This model accounts for the ability of a single Tom20 in yeast to bind to a diverse array of presequences. Although plants contain a protein that is called Tom20 and that has a receptor function in mitochondrial import, it is not orthologous to yeast or mammalian Tom20 (Perry et al., 2006; Lister et al., 2007). However, the NMR structure of plant Tom20 reveals a similar hydrophobic binding pocket. This has been highlighted as a case of convergent evolution of a receptor that uses a similar mechanism of binding to recognize presequences (Lister and Whelan, 2006). Although structural studies reveal the importance of hydrophobic residues for presequence binding, several studies on yeast, mammals, and plants reveal an important role for positively charged residues in presequences for import into mitochondria (Lister et al., 2005; Neupert and Herrmann, 2007). These positively charged residues may play a role in positioning the amphiphilic α-helix for binding to Tom20 and also in subsequent translocation into and across the pores forming proteins of the TOM and TIM (for translocase of the inner membrane) complexes. Movement of the presequence into and across a translocase is explained by the binding chain hypothesis (Pfanner and Geissler, 2001). According to this hypothesis, a presequence binds to higher affinity sites in the import apparatus until it is “trapped” on the inside of the inner membrane by a combination of electrostatic interactions, the net negative charge on the inside of the inner membrane, and binding to matrix-located HSP70 (Zhang and Glaser, 2002).In addition to the fact that plant Tom20s are not orthologous to other Tom20s, plant mitochondria also lack the other two receptor components that have been functionally characterized in yeast, namely Tom70 and Tom22 (Lister et al., 2007). Furthermore, mitochondrial and plastid targeting signals contain significant similarities in plants; thus, plant mitochondrial presequences have evolved to differentiate from the large number and abundant nature of plastid proteins requiring import from the cytosol (Macasev et al., 2000). This raises the question of how similar plant mitochondrial targeting signals are to those of yeast and how they are differentiated from plastid transit peptides. To adequately address these questions, a large number of presequences need to be assembled to define motifs that differentiate presequence classes. Traditionally, the N-terminal sequences of plant mitochondrial proteins have been obtained by Edman degradation either from purified mitochondrial protein complexes or in proteome studies (Braun and Schmitz, 1995; Jänsch et al., 1996; Millar et al., 1998, 1999; Kruft et al., 2001; Bardel et al., 2002). The presequences could only be obtained by comparison of these N-terminal sequences with the preprotein sequence deduced from full-length cDNA sequences, which were only available in a small number of cases. Glaser et al. (1998) presented a list of approximately 100 plant mitochondrial presequences; these were mainly derived from prediction and/or comparisons in homologous cDNA-derived protein sequences with a core set of 31 experimentally proven presequences for plant mitochondrial proteins. Later analysis of 58 experimentally proven plant mitochondrial presequences deposited in the Swiss-Prot database revealed two major classes containing an Arg residue at positions −2 and −3 and one class without any conserved Arg residues (Zhang et al., 2001; Zhang and Glaser, 2002). However, this data set relied on the sequences available at the time that were from a variety of plant species and contained redundant orthologs from similar proteins. This data set also clearly focused on dicot plants, as less than 20% of the sequences were from monocot species.In the chloroplast, N-terminal modification of chloroplast proteins has been shown to be important for protein viability (Pesaresi et al., 2003). N-terminal acetylation can be detected by high-resolution mass spectrometry (MS) through a change in mass of the N-terminal peptide. The recent systematic analysis of the Arabidopsis (Arabidopsis thaliana) chloroplast proteome revealed 47 stroma proteins with N-acetylated residues and 62 without N-acetylated residues (Zybailov et al., 2008). The detection of N-terminal and non-N-terminal acetylated proteins by identifications of semitryptic peptides also allowed analysis of the cleavage sites and potential motifs for cleavage by processing peptidases (Zybailov et al., 2008). However, no systematic experimental analysis of N-terminal modifications and potential cleavage sites of plant mitochondrial proteins has been carried out to date using such an MS approach.In this study, we have determined Arabidopsis and rice (Oryza sativa) mitochondrial protein-targeting presequences and cleavage sites using an MS approach after gel- or liquid chromatography (LC)-based separation and also identified a range of N-terminal modifications of mitochondrial proteins. Validation of this method was performed by false-positive analysis and comparison with previous results in Arabidopsis using an Edman degradation approach (Kruft et al., 2001). We compared the characteristics of the generated Arabidopsis and rice mitochondrial presequences and the cleavage site motifs. Comparison with experimentally proven yeast mitochondrial presequences and Arabidopsis plastid stroma transit peptides allowed consideration of some evolutionary questions and insights into the different signal-recognizing mechanism(s) used to distinguish between organelles.     

Identification of Signals Required for Import of the Soybean FAd Subunit of ATP Synthase into Mitochondria

The requirements for protein import into mitochondria was investigated by using the targeting signal of the F(A)d subunit of soybean mitochondrial ATP synthase attached to two different passenger proteins, its native passenger and soybean alternative oxidase. Both passenger proteins are soybean mitochondrial proteins. Changing hydrophobic residues at positions -24:25 (Phe:Leu), -18:19 (Ile:Leu) and -12:13 (Leu:Ile) of the 31 amino acid cleavable presequence gave more than 50% inhibition of import with both passenger proteins. Some other residues in the targeting signal played a more significant role in targeting of one passenger protein compared to another. Notably changing positive residues (Arg, Lys) had a greater inhibitory affect on import with the native passenger protein, i.e. greater inhibition of import with F(A)d mature protein was observed compared to when alternative oxidase was the mature protein. When using chimeric passenger proteins it was shown that the nature of the mature protein can greatly affect the targeting properties of the presequence. In vivo investigations of the targeting presequence indicated that the presequence of 31 amino acids could not support import of GFP as a passenger protein. However, fusion of the full-length F(A)d coding sequence to GFP did result in mitochondrial localisation of GFP. Using the latter fusion we confirmed the critical role of hydrophobic residues at positions -24:25 and -18:19. These results support the proposal that core mitochondrial targeting features exist in all presequences, but that additional features exist. These features may not be evident with all passenger proteins.     

Import of in-vitro-synthesized glyoxysomal malate dehydrogenase into isolated watermelon glyoxysomes

Glyoxysomal malate dehydrogenase (gMDH; EC 1.1.1.37) is synthesized by a reticulocyte system in the presence of watermelon mRNA (Citrullus vulgaris Schrad., var. Kleckey's Sweet No 6) as a cytosolic, higher-molecular-weight precursor (41 kdalton). We now show that this precursor is posttranslationally sequestered by a crude glyoxysomal fraction or by glyoxysomes purified on a Percoll^R gradient to a proteolytically protected form (60 min proteinase-K treatment at 4° C) with the size of the gMDH subunit (33 kdalton). In the presence of buffer instead of organelles a complete degradation of the precursor is obtained. The in-vitro organelle import, however, depends upon the presence of proteases such as proteinase K or trypsin. After short proteolytic treatments (e.g. 10 min proteinase K at 4° C), the correct processing of the MDH precursor is obtained even in the absence of organelles. This product, however, is not sequestered in vitro to a protease-resistant form by glyoxysomes. The possibility is discussed that under in-vivo conditions pre-gMDH is processed on the outside of the glyoxysomal membrane and transferred immediately after processing into the organelle presumably as a gMDH monomer followed by refolding and dimerization.Abbreviations gMDH glyoxysomal malate dehydrogenase - PMSF phenylmethylsulfonyl fluoride - SDS sodium dodecyl sulfate - TPCK-trypsin trypsin treated with l-1-tosylamide-2-phenylethyl chloromethyl ketone Dedicated to Professor Dr. Hubert Ziegler on the occasion of his 60th birthday     

Recognition and Binding of Mitochondrial Presequences during the Import of Proteins into Mitochondria

Nuclear-encoded mitochondrial proteins are imported into mitochondria due to the presence of a targeting sequence, the presequence, on their amino termini. Presequences, which are typically proteolyzed after a protein has been imported into a mitochondrion, lack any strictly conserved primary structure but are positively charged and are predicted to form amphiphilic -helices. Studies with synthetic peptides corresponding to various presequences argue that presequences can partition nonspecifically into the mitochondrial outer membrane and that the specificity of translocation of precursors into mitochondria may depend on interactions of the presequence with the electrical potential of the inner membrane. Although proteins of the outer membrane that are necessary for the translocation of precursor proteins have been proposed to function as receptors for presequences, the binding of presequences to these proteins has not been demonstrated directly. Proteins of the mitochondrial outer membrane may not be responsible for the specificity of translocation of precursors but may instead function, together with cytosolic molecular chaperones, to maintain precursor proteins in conformations that are competent for translocation as the precursors associate with the mitochondrial surface.