Primary structure and characterisation of a 64 kDa NADH dehydrogenase from the inner membrane of Neurospora crassa mitochondria.

A cDNA clone encoding a mitochondrial NADH dehydrogenase from Neurospora crassa was sequenced. The total DNA sequence encompasses 2570 base pairs and contains an open reading frame of 2019 base pairs coding for a precursor polypeptide of 673 amino acid residues. The protein is encoded by a single-copy gene located to the right side of the centromere in linkage group IV of the fungal genome. The N-terminus of the precursor protein has characteristics of a mitochondrial targeting pre-sequence. The protein displays homology with mitochondrial NADH dehydrogenases from yeast. In contrast to these polypeptides, however, analysis of its primary structure revealed that it contains a well-conserved calcium-binding domain. Rabbit antiserum against the protein expressed in an heterologous system recognises a mitochondrial protein of N. crassa with an apparent molecular mass of 64 kDa. Analysis of the fungal mitochondria by swelling, digitonin fractionation and alkaline treatment indicate that the protein is located in the inner membrane of the organelles, possibly facing the matrix side.     

Expression and function of heterologous forms of malate dehydrogenase in yeast.

The structure of the tricarboxylic acid cycle enzyme malate dehydrogenase is highly conserved in various organisms. To test the extent of functional conservation, the rat mitochondrial enzyme and the enzyme from Escherichia coli were expressed in a strain of Saccharomyces cerevisiae containing a disruption of the chromosomal MDH1 gene encoding yeast mitochondrial malate dehydrogenase. The authentic precursor form of the rat enzyme, expressed using a yeast promoter and a multicopy plasmid, was found to be efficiently targeted to yeast mitochondria and processed to a mature active form in vivo. Mitochondrial levels of the polypeptide and malate dehydrogenase activity were found to be similar to those for MDH1 in wild-type yeast cells. Efficient expression of the E. coli mdh gene was obtained with multicopy plasmids carrying gene fusions encoding either a mature form of the procaryotic enzyme or a precursor form with the amino terminal mitochondrial targeting sequence from yeast MDH1. Very low levels of mitochondrial import and processing of the precursor form were obtained in vivo and activity could be demonstrated for only the expressed precursor fusion protein. Results of in vitro import experiments suggest that the percursor form of the E. coli protein associates with yeast mitochondria but is not efficiently internalized. Respiratory rates measured for isolated yeast mitochondria containing the mammalian or procaryotic enzyme were, respectively, 83 and 62% of normal, suggesting efficient delivery of NADH to the respiratory chain. However, expression of the heterologous enzymes did not result in full complementation of growth phenotypes associated with disruption of the yeast MDH1 gene.     

Isolation, characterization, and sequence analysis of a cDNA clone encoding L-protein, the dihydrolipoamide dehydrogenase component of the glycine cleavage system from pea-leaf mitochondria.

L-protein is the dihydrolipoamide dehydrogenase component of the glycine decarboxylase complex which catalyses, with serine hydroxymethyltransferase, the mitochondrial step of photorespiration. We have isolated and characterized a cDNA from a lambda gt11 pea library encoding the complete L-protein precursor. The derived amino acid sequence indicates that the protein precursor consists of 501 amino acid residues, including a presequence peptide of 31 amino acid residues. The N-terminal sequence of the first 18 amino acid residues of the purified L-protein confirms the identity of the cDNA. Alignment of the deduced amino acid sequence of L-protein with human, porcine and yeast dihydrolipoamide dehydrogenase sequences reveals high similarity (70% in each case), indicating that this enzyme is highly conserved. Most of the residues located in or near the active sites remain unchanged. The results described in the present paper strongly suggest that, in higher plants, a unique dihydrolipoamide dehydrogenase is a component of different mitochondrial enzyme complexes. Confidence in this conclusion comes from the following considerations. First, after fractionation of a matrix extract of pea-leaf mitochondria by gel-permeation chromatography followed by gel electrophoresis and Western-blot analysis, it was shown that polyclonal antibodies raised against the L-protein of the glycine-cleavage system recognized proteins with an Mr of about 60000 in different elution peaks where dihydrolipoamide dehydrogenase activity has been detected. Second, Northern-blot analysis of RNA from different tissues such as leaf, stem, root and seed, using L-protein cDNA as a probe, indicates that the mRNA of the dihydrolipoamide dehydrogenase accumulates to high levels in all tissues. In contrast, the H-protein (a specific protein component of the glycine-cleavage system) is known to be expressed primarily in leaves. Third, Southern-blot analysis indicated that the gene coding for L-protein in pea is most likely to be present in a single copy/haploid genome.     

Sequence and structural requirements of a mitochondrial protein import signal defined by saturation cassette mutagenesis.

The Saccharomyces cerevisiae F1-ATPase beta subunit precursor contains redundant mitochondrial protein import information at its NH2 terminus (D. M. Bedwell, D. J. Klionsky, and S. D. Emr, Mol. Cell. Biol. 7:4038-4047, 1987). To define the critical sequence and structural features contained within this topogenic signal, one of the redundant regions (representing a minimal targeting sequence) was subjected to saturation cassette mutagenesis. Each of 97 different mutant oligonucleotide isolates containing single (32 isolates), double (45 isolates), or triple (20 isolates) point mutations was inserted in front of a beta-subunit gene lacking the coding sequence for its normal import signal (codons 1 through 34 were deleted). The phenotypic and biochemical consequences of these mutations were then evaluated in a yeast strain deleted for its normal beta-subunit gene (delta atp2). Consistent with the lack of an obvious consensus sequence for mitochondrial protein import signals, many mutations occurring throughout the minimal targeting sequence did not significantly affect its import competence. However, some mutations did result in severe import defects. In these mutants, beta-subunit precursor accumulated in the cytoplasm, and the yeast cells exhibited a respiration defective phenotype. Although point mutations have previously been identified that block mitochondrial protein import in vitro, a subset of the mutations reported here represents the first single missense mutations that have been demonstrated to significantly block mitochondrial protein import in vivo. The previous lack of such mutations in the beta-subunit precursor apparently relates to the presence of redundant import information in this import signal. Together, our mutants define a set of constraints that appear to be critical for normal activity of this (and possibly other) import signals. These include the following: (i) mutant signals that exhibit a hydrophobic moment greater than 5.5 for the predicted amphiphilic alpha-helical conformation of this sequence direct near normal levels of beta-subunit import (ii) at least two basic residues are necessary for efficient signal function, (iii) acidic amino acids actively interfere with import competence, and (iv) helix-destabilizing residues also interfere with signal function. These experimental observations provide support for mitochondrial protein import models in which both the structure and charge of the import signal play a critical role in directing mitochondrial protein targeting and import.     

The role of protein structure in the mitochondrial import pathway. Unfolding of mitochondrially bound precursors is required for membrane translocation

In order to examine the influence of protein structure on the post-translational import of a protein into mitochondria, the carboxyl-terminal 129 residues of F1-ATPase beta-subunit precursor (511aa) have been replaced with 61 residues of yeast copper metallothionein. Import of the F1 beta-copper metallothionein (beta CuMT) hybrid into mitochondria was as efficient as that of the F1 beta precursor in the absence of copper. Addition of copper to mitochondrial import reactions, which had no significant effect on import of the F1 beta-subunit precursor, blocked import of the beta CuMT protein. This copper-dependent transport block for the beta CuMT precursor occurred after the precursor was bound to mitochondria. Expression of the beta CuMT protein in vivo revealed that beta CuMT would bind copper and allow growth of a copper-sensitive yeast host on an otherwise inhibitory level of the cation as long as it was localized in the cytoplasm. These data indicate that the binding of copper by beta CuMT renders it refractile for partial unfolding which is necessary for its translocation into mitochondria. These observations provide an alternative scheme for the selection of mutants defective in mitochondrial import.     

Involvement of the TOM complex in external NADH transport into yeast mitochondria depleted of mitochondrial porin1

The protein(s) responsible for metabolite transport through the outer membrane of the yeast Saccharomyces cerevisiae mitochondria depleted of mitochondrial porin (also known as voltage-dependent anion selective channel), termed here porin1, is (are) still unidentified. It is postulated that the transport may be supported by the protein import machinery of the outer membrane, the TOM complex (translocase of the outer membrane). We demonstrate here that in the absence of functional porin1, the blockage of the TOM complex by the fusion protein termed pb(2)-DHFR (consisting of the first 167 amino acids of yeast cytochrome b(2) preprotein connected to mouse dihydrofolate reductase) limits the access of external NADH to mitochondria. It was measured by the ability of the blockage to inhibit external NADH oxidation by the proper dehydrogenase located at the outer surface of the inner membrane. The inhibition depends on external NADH concentration and increases with decreasing amounts of the substrate. In the presence of 1 microg of pb(2)-DHFR per 50 microg of mitochondrial protein almost quantitative inhibition was observed when external NADH was applied at the concentration of 70 nmol per mg of mitochondrial protein. On the other hand, external NADH decreases the levels of pb(2)-DHFR binding at the trans site of the TOM complex in porin1-depleted mitochondria in a concentration-dependent fashion. Our data define an important role of the TOM complex in the transport of external NADH across the outer membrane of porin1-depleted mitochondria.     

The amino acid sequence of the 24-kDa subunit, an iron-sulfur protein, of rat liver mitochondrial NADH dehydrogenase deduced from cDNA sequence

Antiserum directed against bovine heart mitochondrial NADH dehydrogenase has been used to screen a rat liver cDNA expression library in lambda gt11. The insert cDNA of a positive clone was found to represent the 24-kDa subunit of NADH dehydrogenase by epitope selection using nitrocellulose filter containing the expressed proteins. The amino acid sequence deduced from the nucleotide sequence of the cloned cDNA indicated that the 24-kDa subunit is produced as a precursor with an amino-terminal extension, and that its mature form consists of 217 amino acid residues with a molecular weight of 23,933.     

The first twelve amino acids of a yeast mitochondrial outer membrane protein can direct a nuclear-coded cytochrome oxidase subunit to the mitochondrial inner membrane.

We have used an in vivo complementation assay to test whether a given polypeptide sequence can direct an attached protein to the mitochondrial inner membrane. The host is a previously described yeast deletion mutant that lacks cytochrome oxidase subunit IV (an imported protein) and, thus neither assembles cytochrome oxidase in its mitochondrial inner membrane nor grows on the non-fermentable carbon source, glycerol. Growth on glycerol and cytochrome oxidase assembly are restored to the mutant if it is transformed with the gene encoding authentic subunit IV precursor, a protein carrying a 25-residue transient pre-sequence. No restoration is seen with a plasmid encoding a subunit IV precursor whose pre-sequence has been shortened to seven residues. Partial, but significant restoration is achieved by an artificial subunit IV precursor in which the authentic pre-sequence has been replaced by the first 12 amino acids of a 70-kd protein of the mitochondrial outer membrane. If this dodecapeptide is fused to the amino terminus of mouse dihydrofolate reductase (a cytosolic protein), the resulting fusion protein is imported into the matrix of yeast mitochondria in vitro and in vivo. Import in vitro requires an energized inner membrane. We conclude that the extreme amino terminus of the 70-kd outer membrane protein can direct an attached protein across the mitochondrial inner membrane.     

Kinetic regulation of the mitochondrial glycerol-3-phosphate dehydrogenase by the external NADH dehydrogenase in Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, the two most important systems for conveying excess cytosolic NADH to the mitochondrial respiratory chain are external NADH dehydrogenase (Nde1p/Nde2p) and the glycerol-3-phosphate dehydrogenase shuttle. In the latter system, NADH is oxidized to NAD+ and dihydroxyacetone phosphate is reduced to glycerol 3-phosphate by the cytosolic Gpd1p; glycerol 3-phosphate gives two electrons to the respiratory chain via mitochondrial glycerol-3-phosphate dehydrogenase (Gut2p)-regenerating dihydroxyacetone phosphate. Both Nde1p/Nde2p and Gut2p are located in the inner mitochondrial membrane with catalytic sites facing the intermembranal space. In this study, we showed kinetic interactions between these two enzymes. First, deletion of either one of the external dehydrogenases caused an increase in the efficiency of the remaining enzyme. Second, the activation of NADH dehydrogenase inhibited the Gut2p in such a manner that, at a saturating concentration of NADH, glycerol 3-phosphate is not used as respiratory substrate. This effect was not a consequence of a direct action of NADH on Gut2p activity because both NADH dehydrogenase and its substrate were needed for Gut2p inhibition. This kinetic regulation of the activity of an enzyme as a function of the rate of another having a similar physiological function may be allowed by their association into the same supramolecular complex in the inner membrane. The physiological consequences of this regulation are discussed.     

Hexokinase-binding properties of the mitochondrial VDAC protein: Inhibition by DCCD and location of putative DCCD-binding sites

The outer mitochondrial membrane receptor for hexokinase binding has been identified as the VDAC protein, also known as mitochondrial porin. The ability of the receptor to bind hexokinase is inhibited by pretreatment with dicyclohexylcarbodiimide (DCCD). At low concentrations, DCCD inhibits hexokinase binding by covalently labeling the VDAC protein, with no apparent effect on VDAC channel-forming activity. The stoichiometry of [¹⁴C]-DCCD labeling is consistent with one to two high-affinity DCCD-binding sites per VDAC monomer. A comparison between the sequence of yeast VDAC and a conserved sequence found at DCCD-binding sites of several membrane proteins showed two sites where the yeast VDAC amino acid sequence appears to be very similar to the conserved DCCD-binding sequence. Both of these sites are located near the C-terminal end of yeast VDAC (residues 257–265 and 275–283). These results are consistent with a model in which the C-terminal end of VDAC is involved in binding to the N-terminal end of hexokinase.     

Molecular cloning and sequencing of cDNA for yeast porin, an outer mitochondrial membrane protein: a search for targeting signal in the primary structure.

We have cloned a full-length cDNA for yeast porin, the major outer mitochondrial membrane protein from Saccharomyces cerevisiae, and determined its nucleotide sequence. The primary structure of the protein, deduced from the nucleotide sequence, consisted of 283 amino acid residues and its NH2-terminal sequence, Met-Ser-Pro-Pro-Val-Tyr-Ser, coincided with that determined by Edman degradation for yeast porin, except that the initiator methionine was missing in the mature protein. The deduced sequence had an overall polarity index of 46.3%, a value which falls in the normal range for soluble proteins. An evaluation of hydropathy of the protein indicated that the NH2-terminal one third was relatively hydrophilic and the rest of the molecule was rather hydrophobic. An interesting finding was that the NH2-terminal region of yeast porin (consisting of some 50 amino acid residues) shows structural features that resemble those of the corresponding portion of 70-kd protein, which is also a yeast outer mitochondrial membrane protein. We postulate that this NH2-terminal sequence, like that of 70-kd protein, is required for targeting the porin to the outer mitochondrial membrane.     

Ugo1p is a multipass transmembrane protein with a single carrier domain required for mitochondrial fusion

The outer mitochondrial membrane protein Ugo1 forms a complex with the Fzo1p and Mgm1p GTPases that regulates mitochondrial fusion in yeast. Ugo1p contains two putative carrier domains (PCDs) found in mitochondrial carrier proteins (MCPs). Mitochondrial carrier proteins are multipass transmembrane proteins that actively transport molecules across the inner mitochondrial membrane. Mitochondrial carrier protein transport requires functional carrier domains with the consensus sequence PX(D/E)XX(K/R). Mutation of charged residues in this consensus sequence disrupts transport function. In this study, we used targeted mutagenesis to show that charge reversal mutations in Ugo1p PCD2, but not PCD1, disrupt mitochondrial fusion. Ugo1p is reported to be a single-pass transmembrane protein despite the fact that it contains several additional predicted transmembrane segments. Using a combination of protein targeting and membrane extraction experiments, we provide evidence that Ugo1p contains additional transmembrane domains and is likely a multipass transmembrane protein. These studies identify PCD2 as a functional domain of Ugo1p and provide the first experimental evidence for a multipass topology of this essential fusion component.     

Cloning and sequencing of a cDNA encoding the precursor to the 24 kDa iron-sulfur protein of human mitochondrial NADH dehydrogenase

1. We have isolated a cDNA encoding the 24 kDa subunit, an iron-sulfur protein, of mitochondrial NADH dehydrogenase from a human fibroblast cDNA library by colony hybridization using a rat 24 kDa subunit cDNA as a probe. 2. The presequence predicted from the human cDNA sequence is typical of precursors to mitochondrial proteins in a high content of basic residues and in the absence of acidic ones. 3. The mature form of the human 24 kDa subunit shows 95% homology with its rat counterpart. Five cysteine residues are conserved among human, rat and bovine; four of these are expected to be involved in the binding of a binuclear iron-sulfur cluster.     

Functional definition of outer membrane proteins involved in preprotein import into mitochondria

The role of plant mitochondrial outer membrane proteins in the process of preprotein import was investigated, as some of the principal components characterized in yeast have been shown to be absent or evolutionarily distinct in plants. Three outer membrane proteins of Arabidopsis thaliana mitochondria were studied: TOM20 (translocase of the outer mitochondrial membrane), METAXIN, and mtOM64 (outer mitochondrial membrane protein of 64 kD). A single functional Arabidopsis TOM20 gene is sufficient to produce a normal multisubunit translocase of the outer membrane complex. Simultaneous inactivation of two of the three TOM20 genes changed the rate of import for some precursor proteins, revealing limited isoform subfunctionalization. Inactivation of all three TOM20 genes resulted in severely reduced rates of import for some but not all precursor proteins. The outer membrane protein METAXIN was characterized to play a role in the import of mitochondrial precursor proteins and likely plays a role in the assembly of beta-barrel proteins into the outer membrane. An outer mitochondrial membrane protein of 64 kD (mtOM64) with high sequence similarity to a chloroplast import receptor was shown to interact with a variety of precursor proteins. All three proteins have domains exposed to the cytosol and interacted with a variety of precursor proteins, as determined by pull-down and yeast two-hybrid interaction assays. Furthermore, inactivation of one resulted in protein abundance changes in the others, suggesting functional redundancy. Thus, it is proposed that all three components directly interact with precursor proteins to participate in early stages of mitochondrial protein import.     

Yeast mitochondrial ATPase subunit 8, normally a mitochondrial gene product, expressed in vitro and imported back into the organelle.

Subunit 8 of yeast mitochondrial F1F0-ATPase is a proteolipid made on mitochondrial ribosomes and inserted directly into the inner membrane for assembly with the other F0 membrane-sector components. We have investigated the possibility of expressing this extremely hydrophobic, mitochondrially encoded protein outside the organelle and directing its import back into mitochondria using a suitable N-terminal targeting presequence. This report describes the successful import in vitro of ATPase subunit 8 proteolipid into yeast mitochondria when fused to the targeting sequence derived from the precursor of Neurospora crassa ATPase subunit 9. The predicted cleavage site of matrix protease was correctly recognized in the fusion protein. A targeting sequence from the precursor of yeast cytochrome oxidase subunit VI was unable to direct the subunit 8 proteolipid into mitochondria. The proteolipid subunit 8 exhibited a strong tendency to embed itself in mitochondrial membranes, which interfered with its ability to be properly imported when part of a synthetic precursor.     

Screening of binding proteins that interact with human Salvador 1 in a human fetal liver cDNA library by the yeast two-hybrid system

Salvador promotes both cell cycle exit and apoptosis through the modulation of both cyclin E and Drosophila inhibitor of apoptosis protein in Drosophila. However, the cellular function of human Salvador (hSav1) is rarely reported. To screen for novel binding proteins that interact with hSav1, the cDNA of hSav1 was cloned into a bait protein plasmid, and positive clones were screened from a human fetal liver cDNA library by the yeast two-hybrid system. hSav1 mRNA was expressed in yeast and there was no self-activation and toxicity in the yeast strain AH109. Twenty proteins were found to interact with hSav1, including HS1 (haematopoietic cell specific protein1)-associated protein X-1 (HAX-1); neural precursor cell expressed, developmentally down-regulated 9, pyruvate kinase, liver and RBC, cytochrome c oxidase subunit Vb, enoyl coenzyme A hydratase short chain 1, and NADH dehydrogenase (ubiquinone) 1 beta subcomplex, demonstrating that the yeast two-hybrid system is an efficient method for investigating protein interactions. Among the identified proteins, there were many mitochondrial proteins, indicating that hSav1 may play a role in mitochondrial function. We also confirmed the interaction of HAX-1 and hSav1 in mammalian cells. This investigation provides functional clues for further exploration of potential apoptosis-related proteins in disease biotherapy.