Functional analysis of mitochondrial protein import in yeast

In order to facilitate studies on protein localization to and sorting within yeast mitochondria, we have designed an experimental system that utilizes a new vector and a functional assay. The vector, which we call an LPS plasmid (for leader peptide substitution), employs a yeast COX5a gene (the structural gene for subunit Va of the inner membrane protein complex cytochrome c oxidase) as a convenient reporter for correct mitochondrial localization. Using in vitro mutagenesis, we have modified COX5a so that the DNA sequences encoding the wild-type subunit Va leader peptide can be precisely deleted and replaced with a given test sequence. The substituted leader peptide can then be analyzed for its ability to direct subunit Va to the inner mitochondrial membrane (to target and sort) by complementation or other in vivo assays. In this study we have tested the ability of several heterologous sequences to function in this system. The results of these experiments indicate that a functional leader peptide is required to target subunit Va to mitochondria. In addition, leader peptides, or portions thereof, derived from proteins located in other mitochondrial compartments can also be used to properly localize this polypeptide. The results presented here also indicate that the information necessary to sort subunit Va to the inner mitochondrial membrane does not reside in the leader peptide but rather in the mature subunit Va sequence.     

Mitochondrial import of cytochrome c oxidase subunit VIIa in Saccharomyces cerevisiae. Identification of sequences required for mitochondrial localization in vivo

Subunit VIIa of yeast cytochrome c oxidase is a small (59 amino acids) protein of the inner mitochondrial membrane that lacks a cleavable amino-terminal presequence. To identify regions within this polypeptide that are essential for its import, gene fusions were constructed using a leader peptide substitution vector (pLPS) developed in this laboratory (Glaser, S. M., Trueblood, C. E., Dircks, L. K., Poyton, R. O., and Cumsky, M. G. (1988) J. Cell. Biochem. 36, 275-287). In this vector, oligonucleotide sequences encoding all or part of subunit VIIa were fused in-frame with the coding region of mature cytochrome c oxidase subunit Va. The plasmid pLPS is ideal for assaying protein sequences for their ability to direct mitochondrial import in vivo since subunit Va's leader peptide is essential for import and because subunit V is required for cytochrome c oxidase activity and respiration. Strains containing these fusions but lacking both subunit V genes (COX5a and COX5b) were analyzed to determine whether the chimeric protein is directed to mitochondria. Our findings indicate that the amino-terminal 17 amino acids of subunit VIIa are sufficient to localize subunit Va to the mitochondrion and that a 6-amino acid-long region within the amino terminus (Gly8-Arg13) is essential. In addition, some import (approximately 10% of wild type) is observed with the highly charged carboxyl terminus of subunit VIIa, suggesting that the subunit may contain redundancy in its import information.     

A yeast mitochondrial leader peptide functions in vivo as a dual targeting signal for both chloroplasts and mitochondria.

A fusion protein was expressed in transgenic tobacco and yeast cells to examine the functional conservation of mechanisms for importing precursor proteins from the cytosol into mitochondria and chloroplasts. The test protein consisted of the mitochondrial leader peptide from the yeast precursor to cytochrome oxidase subunit Va (prC5) fused to the reporter protein chloramphenicol acetyltransferase. This protein, denoted prC5/CAT, was transported into the mitochondrial interior in yeast and tobacco cells. In both organisms, the mitochondrial form of prC5/CAT was smaller than the primary translation product, suggesting that proteolytic processing occurred during the transport process. prC5/CAT also was translocated into chloroplasts in vivo, accumulating to approximately the same levels as in plant mitochondria. However, accumulation of prC5/CAT in chloroplasts relative to mitochondria varied with the conditions under which plants were grown. The chloroplast form of prC5/CAT also appeared to have been proteolytically processed, yielding a mature protein of the same apparent size as that seen in mitochondria of either tobacco or yeast. Chloramphenicol acetyltransferase lacking a mitochondrial targeting peptide did not associate with either chloroplasts or mitochondria. The results demonstrated that in plant cells a single leader peptide can interact functionally with the protein translocation systems of both chloroplasts and mitochondria, and raised the possibility that certain native proteins might be shared between these two organelles.     

Duplication of leader sequence for protein targeting to mitochondria leads to increased import efficiency

We describe a novel method for enhancing protein import into mitochondria, by tandemly duplicating the N-terminal cleavable leader peptide using a gene manipulation strategy. The import into isolated yeast mitochondria of passenger proteins (yeast mitochondrial ATP synthase subunits 8 and 9 and some mutagenised derivatives) that show little or no import when endowed with one such leader (that of Neurospora crassa mitochondrial ATP synthase subunit 9) is remarkably improved when the leader is tandemly duplicated. The import of these chimaeric proteins bearing a double leader is so rapid that a series of partially processed precursor intermediates accumulates inside the mitochondria before the final proteolytic release of leader sequences from the passenger proteins. It is considered that the duplicated leader greatly accelerates delivery of the import precursors to outer membrane receptor elements and the associated translocation systems, thereby enhancing precursor uptake into mitochondria.     

An unusual mitochondrial import pathway for the precursor to yeast cytochrome c oxidase subunit Va

We have studied the import of the precursor to yeast cytochrome c oxidase subunit Va, a protein of the mitochondrial inner membrane. Like the majority of mitochondrial precursor proteins studied thus far, import of presubunit Va was dependent upon both a membrane potential (delta psi) and the hydrolysis of ATP. However, the levels of ATP necessary for the import of presubunit Va were significantly lower than those required for the import of a different mitochondrial precursor protein, the beta subunit of the F1-ATPase. The rate of import of presubunit Va was found to be unaffected by temperature over the range 0 to 30 degrees C, and was not facilitated by prior denaturation of the protein. These results, in conjunction with those of an earlier study demonstrating that presubunit Va could be efficiently targeted to mitochondria with minimal presequences, suggest that the subunit Va precursor normally exists in a loosely folded conformation. Presubunit Va could also be imported into mitochondria that had been pretreated with high concentrations of trypsin or proteinase K (1 mg/ml and 200 micrograms/ml, respectively). Furthermore, the rate of import into trypsin-treated mitochondria, at both 0 and 30 degrees C, was identical to that observed with the untreated organelles. Thus, import of presubunit Va is not dependent upon the function of a protease-sensitive surface receptor. When taken together, the results of this study suggest that presubunit Va follows an unusual import pathway. While this pathway uses several well-established translocation steps, in its entirety it is distinct from either the receptor-independent pathway used by apocytochrome c, or the more general pathway used by a majority of mitochondrial precursor proteins.     

Studies on the import into mitochondria of yeast ATP synthase subunits 8 and 9 encoded by artificial nuclear genes

Direct fusions have been constructed between each of subunits 8 and 9 from mitochondrial ATPase of Saccharomyces cerevisiae, proteins normally encoded inside mitochondria, and the cleavable N-terminal transit peptide from the nuclearly encoded precursor to subunit 9 of Neurospora crassa mitochondrial ATPase. The subunit 8 construct was imported efficiently into isolated yeast mitochondria and was processed at or very near the fusion point. When expressed in vivo from its artificial nuclear gene, this cytoplasmically synthesized form of subunit 8 restored the growth defects of aap 1 mutants unable to produce subunit 8 inside the mitochondria. The subunit 9 construct was, however, unable to be imported into isolated mitochondria and could not, following nuclear expression in vivo, complement growth defects in mitochondrial oli 1 mutants. This behaviour is contrasted with the previously demonstrated import competence of another yeast subunit 9 fusion, bearing the first five residues of mature N. crassa subunit 9 interposed between its own transit peptide and the yeast subunit 9 moiety.     

Effect of deletions within the leader peptide of pre-ornithine transcarbamylase on mitochondrial import

The uptake of the cytoplasmically synthesized mammalian enzyme, ornithine transcarbamylase, into mitochondria is directed by an N-terminal peptide of 32 amino acids. We have investigated some of the structural requirements for the import of the enzyme from rat liver into isolated mitochondria and into mitochondria of COS cells transfected with cDNA encoding the precursor form of ornithine transcarbamylase. Deletion of 21 amino acids from the N terminus of the leader peptide blocked the import of the precursor; deletion of 5 amino acids at positions 15-19 from the N terminus of the leader peptide had no deleterious effect on the import of the enzyme, nor on the processing and assembly of subunits in mitochondria. The region deleted contained three of eight basic residues in the leader peptide suggesting that specific structural elements containing basic residues, rather than the general basic nature of the leader, may be involved in mitochondrial import.     

Import of the malate dehydrogenase precursor by mitochondria. Cleavage within leader peptide by matrix protease leads to formation of intermediate-sized form

The mitochondrial matrix enzyme malate dehydrogenase (MDH) is synthesized on cytoplasmic polysomes as a larger precursor (pMDH) with an NH2-terminal leader peptide of 24 amino acids. Import of in vitro synthesized MDH into mitochondria results in formation of the mature-sized subunit. We report here that the conversion of pMDH to mMDH occurs via two distinct cleavage events within the leader peptide. First, pMDH is cleaved to an intermediate form (iMDH) of MDH. Conversion of the precursor to the intermediate form is catalyzed by a protease localized to the mitochondrial matrix. The cleavage of pMDH to iMDH involves the removal of 15 amino acids from the NH2 terminus of the pMDH leader peptide. The iMDH is subsequently cleaved, also by a matrix protease, to mature MDH in a reaction which is O-phenanthroline-sensitive. Cleavage to iMDH and to mature MDH occurs prior to completion of translocation of the MDH polypeptide chain into the mitochondrial matrix.     

Expression of human ferredoxin in Saccharomyces cerevisiae: mitochondrial import of the protein and assembly of the [2Fe-2S] center.

Vertebrate ferredoxins function in the transfer of reducing equivalents from NADPH:ferredoxin oxidoreductase to cytochrome P450 enzymes involved in steroid metabolism. We report here the expression of human mitochondrial ferredoxin in the yeast Saccharomyces cerevisiae. The full-length ferredoxin protein containing the ferredoxin mitochondrial leader sequence could not be stably expressed in S. cerevisiae, but a fusion protein consisting of the mature portion of ferredoxin linked to the mitochondrial leader sequence of the S. cerevisiae cytochrome c oxidase subunit Va protein (COX5a) could be stably expressed. The COX5a:ferredoxin fusion protein was targeted to the mitochondria as a preprotein and was cleaved at the normal processing site of the COX5a presequence during import into the matrix. Absorption spectra and electron transfer activity of the isolated fusion protein established that the [2Fe-2S] center was correctly assembled and incorporated into the recombinant ferredoxin in this heterologous system.     

Deletion of the Leader Peptide of the Mitochondrially Encoded Precursor of Saccharomyces Cerevisiae Cytochrome C Oxidase Subunit II

Cytochrome c oxidase subunit II (Cox2p) of Saccharomyces cerevisiae is synthesized within mitochondria as a precursor, pre-Cox2p. The 15-amino acid leader peptide is processed after export to the intermembrane space. Leader peptides are relatively unusual in mitochondrially coded proteins: indeed mammalian Cox2p lacks a leader peptide. We generated two deletions in the S. cerevisiae COX2 gene, removing either the leader peptide (cox2-20) or the leader peptide and processing site (cox2-21) without altering either the promoter or the mRNA-specific translational activation site. When inserted into mtDNA, both deletions substantially reduced the steady-state levels of Cox2p and caused a tight nonrespiratory phenotype. A respiring pseudorevertant of the cox2-20 mutant was heteroplasmic for the original mutant mtDNA and a ρ(-) mtDNA whose deletion fused the first 251 codons of the mitochondrial gene encoding cytochrome b to the cox2-20 sequence. The resulting fusion protein was processed to yield functional Cox2p. Thus, the presence of amino-terminal cytochrome b sequence bypassed the need for the pre-Cox2p leader peptide. We propose that the pre-Cox2p leader peptide contains a targeting signal necessary for membrane insertion, without which it remains in the matrix and is rapidly degraded.     

Inhibition of purified Escherichia coli leader peptidase by the leader (signal) peptide of bacteriophage M13 procoat.

The leader peptide of bacteriophage M13 procoat inhibited the cleavage of M13 procoat or pre-maltose-binding protein by purified Escherichia coli leader peptidase. This finding confirms inferences that the leader is the primary site of enzyme recognition and suggests a rationale for the rapid hydrolysis of leader peptides in vivo.     

The ornithine transcarbamylase leader peptide directs mitochondrial import through both its midportion structure and net positive charge

The cytoplasmically synthesized precursor of the mitochondrial matrix enzyme, ornithine transcarbamylase (OTC), is targeted to mitochondria by its NH2-terminal leader peptide. We previously established through mutational analysis that the midportion of the OTC leader peptide is functionally required. In this article, we report that study of additional OTC precursors, altered in either a site-directed or random manner, reveals that (a) the midportion, but not the NH2-terminal half, is sufficient by itself to direct import, (b) the functional structure in the midportion is unlikely to be an amphiphilic alpha-helix, (c) the four arginines in the leader peptide contribute collectively to import function by conferring net positive charge, and (d) surprisingly, proteolytic processing of the leader peptide does not require the presence of a specific primary structure at the site of cleavage, in order to produce the mature OTC subunit.     

Topology of subunits of the mammalian cytochrome c oxidase: relationship to the assembly of the enzyme complex.

The arrangement of three subunits of beef heart cytochrome c oxidase, subunits Va, VIa, and VIII, has been explored by chemical labeling and protease digestion studies. Subunit Va is an extrinsic protein located on the C side of the mitochondrial inner membrane. This subunit was found to label with N-(4-azido-2-nitrophenyl)-2-aminoethane[35S]sulfonate and sodium methyl 4-[3H]formylphenyl phosphate in reconstituted vesicles in which 90% of cytochrome c oxidase complexes were oriented with the C domain outermost. Subunit VIa was cleaved by trypsin both in these reconstituted vesicles and in submitochondrial particles, indicating a transmembrane orientation. The epitope for a monoclonal antibody (mAb) to subunit VIa was lost or destroyed when cleavage occurred in reconstituted vesicles. This epitope was localized to the C-terminal part of the subunit by antibody binding to a fusion protein consisting of glutathione S-transferase (G-ST) and the C-terminal amino acids 55-85 of subunit VIa. No antibody binding was obtained with a fusion protein containing G-ST and the N-terminal amino acids 1-55. The mAb reaction orients subunit VIa with its C-terminus in the C domain. Subunit VIII was cleaved by trypsin in submitochondrial particles but not in reconstituted vesicles. N-Terminal sequencing of the subunit VIII cleavage product from submitochondrial particles gave the same sequence as the untreated subunit, i.e., ITA, indicating that it is the C-terminus which is cleaved from the M side. Subunits Va and VIII each contain N-terminal extensions or leader sequences in the precursor polypeptides; subunit VIa is made without an N-terminal extension.     

A synthetic presequence reversibly inhibits protein import into yeast mitochondria

We show that a synthetic peptide corresponding to the N-terminal 22 residues of the cytochrome c oxidase subunit IV presequence blocked import of pre-subunit IV into yeast mitochondria. The 22-residue peptide pL4-(1-22) did not alter the electrical potential across the mitochondrial inner membrane (the delta psi). Inhibition of import was reversible and could be overcome by the addition of increased amounts of precursor. Two other peptides, pL4-(1-16) and pL4-(1-23), which correspond to, respectively, the N-terminal 16 and 23 residues of the same presequence, also blocked import of pre-subunit IV. However, pL4-(1-16) was a much weaker inhibitor of import, while the inhibitory effect of pL4-(1-23) was due to its ability to completely collapse the delta psi. pL4-(1-22) seems to be a general inhibitor of mitochondrial import, in that it also blocked uptake of several other proteins. These included the precursors of the yeast proteins cytochrome c oxidase subunit Va, the F1-ATPase beta subunit, mitochondrial malate dehydrogenase, and the ATP/ADP carrier. In addition, uptake of two non-yeast precursor proteins (human ornithine transcarbamylase and a cytochrome oxidase subunit IV-dihydrofolate reductase fusion), was also blocked by the peptide. Subsequent studies revealed that pL4-(1-22) did not block the initial recognition or binding of proteins to mitochondria. Rather, our results suggest that the peptide acts at a subsequent translocation step which is common to the import pathways of many different precursor proteins.     

Import Pathway of Nuclear-Encoded Cytochrome c Oxidase Subunit 2 Using Yeast as a Model

Abstract: Subunit 2 of cytochrome c oxidase (Cox2) is a mitochondrial-encoded protein in most organisms. In soybean Glycine max a second Cox2 gene was identified in the nucleus which is functional, whereas the mitochondrial-encoded cox2 gene is silent. For import and sorting of the nuclear-encoded soybean Cox2 protein ( Gm Cox2p) into mitochondria, the protein has acquired an N-terminal extension of 136 amino acid residues that is cleaved off in three steps during import. To study the function and processing of the Gm Cox2p leader peptide, we used yeast as a model system. Using different leader peptide-GFP constructs, we were able to show that the i₁ intermediate is generated in the mitochondrial matrix and the mature protein is generated in the inner membrane space. Mitochondrial processing peptidase (MPP) is involved in processing the first part of the leader peptide, processing of the last part is catalysed by the inner membrane peptidase (IMP). Oxa1p is necessary for insertion of the protein into the inner mitochondrial membrane. Gm Cox2p therefore utilises many of the same components as its mitochondrial-encoded predecessor, for sorting and maturation, following its import into the mitochondria.     

Assembly of imported subunit 8 into the ATP synthase complex of isolated yeast mitochondria

This study concerns the assembly into a multisubunit enzyme complex of a small hydrophobic protein imported into isolated mitochondria. Subunit 8 of yeast mitochondrial ATPase (normally a mitochondrial gene product) was expressed in vitro as a chimaeric precursor N9L/Y8-1, which includes an N-terminal-cleavable transit peptide to direct its import into mitochondria. Assembly into the enzyme complex of the imported subunit 8 was monitored by immunoadsorption using an immobilized anti-F1-beta monoclonal antibody. Preliminary experiments showed that N9L/Y8-1 imported into normal rho+ mitochondria, with its complement of fully assembled ATPase, did not lead to an appreciable assembly of the exogenous subunit 8. With the expectation that mitochondria previously depleted of subunit 8 could allow such assembly in vitro, target mitochondria were prepared from genetically modified yeast cells in which synthesis of subunit 8 was specifically blocked. Initially, mitochondria were prepared from strain M31, a mit- mutant completely incapable of intramitochondrial biosynthesis of subunit 8. These mit- mitochondria however were unsuitable for assembly studies because they could not import protein in vitro. A controlled depletion strategy was then evolved. An artificial nuclear gene encoding N9L/Y8-1 was brought under the control of a inducible promoter GAL1. This regulated gene construct, in a low copy number yeast expression vector, was introduced into strain M31 to generate strain YGL-1. Galactose control of the expression of N9L/Y8-1 was demonstrated by the ability of strain YGL-1 to grow vigorously on galactose as a carbon source, and by the inability to utilize ethanol alone for prolonged periods of growth. The measurement of bioenergetic parameters in mitochondria from YGL-1 cells experimentally depleted of subunit 8, by transferring growing cells from galactose to ethanol, was consistent with the presence in mitochondria of a mosaic of ATPase, namely fully assembled functional ATPase complexes and partially assembled complexes with defective F0 sectors. These mitochondria demonstrated very efficient import of N9L/Y8-1 and readily incorporated the imported processed subunit 8 protein into ATPase. Comparison of the kinetics of import and assembly of subunit 8 showed that assembly was noticeably delayed with respect to import. These findings open the way to a new systematic analysis of the assembly of imported proteins into multisubunit mitochondrial enzyme complexes.