Transport of proteins across the mitochondrial outer membrane. A precursor form of the cytoplasmically made intermembrane enzyme cytochrome c peroxidase.

Cytochrome c peroxidase, a cytoplasmically made enzyme located between the inner and outer membrane of yeast mitochondria, is synthesized as larger precursor in a reticulocyte cell-free lysate as well as in pulsed yeast spheroplasts. When the pulsed spheroplasts are chased, the precursor is converted to the mature apoprotein. When the in vitro synthesized precursor is incubated with isolated yeast mitochondria in the absence of protein synthesis, it is cleaved to the mature form; the mature form co-sediments with the mitochondria and is resistant to externally added proteases. These results, in conjunction with those reported earlier (Maccecchini, M.-L., Rudin, Y., Blobel, G., and Schatz, G. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 343-347) suggest that the mechanism of protein transport into the mitochondrial intermembrane space is quite similar to that of protein transport into the matrix or the inner membrane.     

Cytochrome c oxidase from bakers' yeast. IV. Immunological evidence for the participation of a mitochondrially synthesized subunit in enzymatic activity.

In order to study the role of the individual subunits of yeast cytochrome c oxidase, rabbit antisera were prepared against Subunit II (a mitochondrially made polypeptide) and Subunit VI (a cytoplasmically made polypeptide). Antisera were also obtained against a mixture of the two mitochondrially made subunits (I PLUS II) and against mixtures of the following cytoplasmically made subunits: (IV PLUS VI); (V PLUS VII); and (IV PLUS V PLUS VI PLUS VII). Neither anti-II serum nor anti-VI serum cross-reacted with any of the other six subunits of cytochrome c oxidase as judged by a sensitive ring test or by double diffusion in agarose gels. Anti-II serum inhibited the oxidation of ferrocytochrome c by purified yeast cytochrome c oxidase or by freshly isolated as well as sonically fragmented yeast mitochondria. Anti-(V, VII) serum and anti-(IV, V, VI, VII) serum were also strongly inhibitory. Anti-VI serum and anti-(IV, VI) serum inhibited only weakly. If purified cytochrome c oxidase was inhibited with a saturating amount of anti-VI serum, anti-II serum elicited a further increment of inhibition, as would be expected if the inhibitory effects of these two antisera involved different antigenic sites on the holoenzyme. Each of the antisera precipitated all seven cytochrome c oxidase subunits from crude mitochondrial extracts. However, anti-VI and, particularly, anti-II were much less effective precipitants than antisera against Subunits IV to VII or antisera against the holoenzyme. These data suggest that the oxidation of ferrocytochrome c by cytochrome c oxidase required both mitochondrially as well as cytoplasmically made subunits.     

Mitochondrial import of rat pre-ornithine transcarbamylase: accurate processing of the precursor form is not required for uptake into mitochondria, nor assembly into catalytically active enzyme

Mitochondrial uptake of the cytoplasmically synthesized precursor of the mammalian enzyme ornithine transcarbamylase is mediated by an N-terminal leader sequence of 32 amino acids. In the mitochondrial matrix, the precursor form is processed to the mature subunit by proteolytic removal of this pre-sequence and in the enzyme from rat liver it has been suggested that this occurs in a two-step process which involves an intermediate cleavage at residue 24. We show that deletion of residues 20-26 spanning this intermediate cleavage site prevents correct processing to the mature subunit but it does not prevent mitochondrial targeting and internalization or assembly of the incorrectly processed product into a catalytically active enzyme. The incorrectly processed enzyme, which is larger than the normal mature enzyme, is nevertheless more susceptible to proteolytic degradation in permanently transfected human cells than the correctly processed enzyme.     

Kinetics of assembly of complex III into the yeast mitochondrial membrane. Evidence for a precursor to the iron-sulfur protein

Complex III immunoprecipitated from yeast cells labeled in vivo with [35S]sulfate or [3H]leucine contained seven subunits with molecular weights ranging from 15,000 to 47,000 when analyzed by electrophoresis on polyacrylamide gels. The subunit composition of the immunoprecipitates was identical with that of the purified complex III isolated from bakers' yeast suggesting that the antiserum recognizes the holoenzyme assembled properly in the membrane (Sidhu, A., and Beattie, D.S. (1982) J. Biol. Chem. 257, 7879-7886). Kinetic studies using double-labeled yeast cells followed by immunoprecipitation of complex III indicated that the subunits of the complex are assembled into the holoenzyme at very different rates. Cytochromes b and c1 and the 15,000-dalton subunit were the first polypeptides to be assembled into the complex with a half-time of labeling of 2.0-2.4 min. Core protein I and the iron-sulfur protein were inserted more slowly into the complex with a half-time of labeling of 4.6 and 5.3 min, respectively. Calculations of precursor pool sizes of the subunits indicated that for both core protein I and the iron-sulfur protein, there are large pools of precursors. The iron-sulfur protein was synthesized in vivo as a larger precursor polypeptide of molecular mass 28,000 Da. The precursor was subsequently cleaved, in a process requiring an energized mitochondrial inner membrane, into an intermediate form 1,500 Da larger than the mature subunit. The conversion of the intermediate to the mature form occurred in the inner mitochondrial membrane.     

The role of oxygen in the biosynthesis of cytochrome c oxidase of yeast mitochondria.

The formation of cytochrome c oxidase in yeast is dependent on oxygen. In order to examine the oxygen-dependent formation of the active enzyme, the effect of oxygen on the synthesis and the assembly of cytochrome c oxidase subunits was studied. Pulse-labeling experiments revealed that oxygen has no significant immediate effect on the synthesis of the three mitochondrially made subunits I to III; however, its presence causes subunits I and II to form a complex with the cytoplasmically made subunits VI and VII. This "assembly-inducing" effect can be demonstrated with intact yeast cells as well as with isolated mitochondria. It is independent of cytoplasmic or mitochondrial protein synthesis. After anaerobic growth for 10 or more generations, the intracellular concentrations of individual cytochrome c oxidase subunits drop 10- to 100-fold. Most of these residual subunits are not assembled within a functional cytochrome c oxidase molecule.     

Evidence for the sequential assembly of cytochrome oxidase subunits in rat liver mitochondria.

The assembly of cytochrome oxidase was studied in isolated rat liver mitochondria and isolated rat hepatocytes labelled in vitro with L-[35S]methionine. This was achieved by studying the temporal association of radioactive subunits which are immunoabsorbed with antibodies against subunits I, II and the holoenzyme. Antibodies against the holoenzyme were shown to be highly specific for subunit V. The results show that subunit I appears in the holoenzyme late in the assembly process. No radioactive subunit I is absorbed with antiserum against subunit II or the holoenzyme (subunit V) after a 30 min pulse in either isolated mitochondria or hepatocytes. However, both antisera absorb radioactive subunits I after a 150 min chase in isolated hepatocytes. This was confirmed using antibodies against subunit I, which absorbed only radioactive subunit I after a 30 min pulse but absorbed radioactive subunits I-III and VI after a 150 min chase. Thus, the late assembly of radioactive subunit I is explained by a temporal sequence in the assembly process and not by the presence of a large, non-radioactive pool of subunit I. Using the above approach and the three specific antisera, the following temporal sequence in the assembly of cytochrome oxidase was established. Subunits II and III assemble rapidly with each other or with cytoplasmically translated subunit VI. This complex of three peptides in turn assembles slowly with subunit I or with the other cytoplasmically translated subunits. The early association of subunit VI with the mitochondrially translated subunits II and III suggests a possible role of the former in integration of the holoenzyme.     

The nucleotide sequence of the HEM1 gene and evidence for a precursor form of the mitochondrial 5-aminolevulinate synthase in Saccharomyces cerevisiae

The biosynthesis of yeast 5-aminolevulinate (ALA) synthase, a mitochondrial protein encoded by the nuclear HEM1 gene, has been studied in vitro in a cell-free translation system and in vivo in whole cells. In vitro translation of mRNA hybrid-selected by the cloned HEM1 gene, or of total RNA followed by immunoprecipitation with anti-(ALA synthase) antibody yielded a single polypeptide of higher molecular mass than the purified ALA synthase. This larger form, also seen in pulse-labeled cells, can be post-translationally processed by isolated mitochondria. These results show that the cytoplasmically made ALA synthase is synthesized with a cleavable extension which was estimated to be about 3.5 kDa by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The complete nucleotide sequence of the HEM1 gene and its flanking regions was determined. The 5' ends of the HEM1 mRNAs map from -76 to -63 nucleotides upstream of the translation initiation codon. The open reading frame of 1644 base pairs encodes a protein of 548 amino acids with a calculated Mr of 59,275. The predicted amino-terminal sequence of the protein is strongly basic (five basic and no acidic amino acids within the first 35 residues), rich in serine and threonine and must represent the transient presequence that targets this protein to the mitochondria. Comparison of deduced amino acid sequences indicates a clear homology between the mature yeast and chick embryo liver ALA synthases.     

A neutral metallo endoprotease involved in the processing of an F1-ATPase subunit precursor in mitochondria

A post-translational processing assay of the precursor to the yeast F1-ATPase subunit has been utilized to examine a mitochondrial endoprotease which cleaves this subunit precursor to the size of a mature subunit. The endoprotease is extracted from purified mitochondria as a soluble complex of Mr = 115,000 which is composed of subunits of lower molecular weight when examined on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It exhibits a pH optimum of between pH 7 and 8 and is inactive at pH 6.5 and below. The mitochondrial endoprotease is insensitive to serine esterase inhibitors, but is inhibited by EDTA and o-phenanthroline. Restoration of precursor subunit processing activity in the presence of metal chelators is strictly dependent on excess Co2+ and Mn2+ over other heavy metals examined. These and additional data indicate that this soluble metallo endoprotease is involved in the processing of other cytoplasmically synthesized precursor subunits of the ATPase complex in addition to the subunit 2 precursor. The role of this processing enzyme in the assembly of mitochondrial inner membrane complexes is discussed in light of the current model of mitochondrial biogenesis.     

Separation, amino-terminal sequence and cell-free synthesis of the smallest subunit of sweet potato cytochrome c oxidase

The smallest subunit (V) of sweet potato cytochrome c oxidase was separated into three polypeptides, Va, Vb and Vc with different molecular masses (7.4 kDa, 6.8 kDa and 6.2 kDa respectively) by highly resolving sodium dodecylsulfate polyacrylamide gel electrophoresis. Antibody against subunit V reacted specifically with the polypeptide Vc. When polyadenylated mRNA from sweet potato root tissue was translated in a wheat germ cell-free system, the smallest subunit (Vc) of the polypeptides was synthesized to the same size as the mature form, which suggests that the mature subunit retains the signal for import into mitochondria. Within the N-terminal first 25 amino acids there is a stretch of 16 non-polar residues, periodically linked by basic residues, which might form an amphiphilic helix as the targeting signal.     

Mitochondrial assembly in respiration-deficient mutants of Saccharomyces cerevisiae. IV. Effects of nuclear amber suppressors on the accumulation of a mitochondrially made subunit of cytochrome c oxidase.

Earlier studies from this laboratory have shown that cytochrome c oxidase from bakers' yeast contains seven subunits, three of which are made in the mitochondrion (Mason, T. L., and Schatz, G. (1973) J. Biol. Chem. 248, 1355). Moreover, a cytochrome c oxidase-less yeast mutant (pet 494-1) was isolated which lacked one of the mitochondrially made subunits (Ebner, E., Mason, T. L., and Schatz, G. (1973) J. Biol. Chem. 248, 5369). Surprisingly, the mutated gene was localized in the nucleus. The results presented here demonstrate that this mutant phenotype can be suppressed by nuclear amber suppressors which affect translation on cytoplasmic ribosomes. This fact was established by two methods, (a) By constructing pet 494-1 strains possessing various amber and ochre markers, isolating respiring revertants from these strains, and demonstrating co-reversion of the amber (but not of the ochre) markers. (b) By coupling the pet 494-1 allele with the well characterized amber suppressor gene SUP 4-3. These data show that suppressor genes located on nuclear chromosomes may control the accumulation of a mitochondrially synthesized polypeptide. The present results also allow some tentative conclusions about the mechanism of the pet 494 mutation. Because it is highly unlikely that the cytoplasmic and the mitochondrial translation system share a common suppressor, the pet 494 locus probably does not code for the missing mitochondrially made subunit, but for a cytoplasmically made protein. This as yet unidentified protein seems to control the synthesis or the integration of the mitochondrially made subunit. Nuclear suppressor genes may thus be useful tools for studying the role of cytoplasmic protein synthesis in mitochondrial formation.     

Complementation of deletion mutants in the genes encoding the F1-ATPase by expression of the corresponding bovine subunits in yeast S. cerevisiae.

The F1F0 ATP synthase is composed of the F1-ATPase which is bound to F0, in the inner membrane of the mitochondrion. Assembly and function of the enzyme is a complicated task requiring the interactions of many proteins for the folding, import, assembly, and function of the enzyme. The F1-ATPase is a multimeric enzyme composed of five subunits in the stoichiometry of alpha3beta3gammadeltaepsilon. This study demonstrates that four of the five bovine subunits of the F1-ATPase can be imported and function in an otherwise yeast enzyme effectively complementing mutations in the genes encoding the corresponding yeast ATPase subunits. In order to demonstrate this, the coding regions of each of the five genes were separately deleted in yeast providing five null mutant strains. All of the strains displayed negative or a slow growth phenotype on medium containing glycerol as the carbon source and strains with a null mutation in the gene encoding the gamma-, delta- or epsilon-gene became completely, or at a high frequency, cytoplasmically petite. The subunits of bovine F1 were expressed individually in the yeast strains with the corresponding null mutations and targeted to the mitochondrion using a yeast mitochondrial leader peptide. Expression of the bovine alpha-, beta-, gamma-, and epsilon-, but not the delta-, subunit complemented the corresponding null mutations in yeast correcting the corresponding negative phenotypes. These results indicate that yeast is able to import, assemble subunits of bovine F1-ATPase in mitochondria and form a functional chimeric yeast/bovine enzyme complex.     

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

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

The presence of the iron-sulfur protein (subunit V) of complex III in mitochondria of heme-deficient yeast cells lacking iron-sulfur clusters detectable by electron paramagnetic resonance

The presence of subunit V, the iron-sulfur protein, of complex III has been demonstrated in mitochondria from a mutant of Saccharomyces cerevisiae which lacks 5-aminolevulinic acid synthase and, hence, is devoid of heme. The mature form (24 K Da) of the iron-sulfur protein was observed in equal amounts in the heme-deficient and heme-sufficient cells with antiserum against subunit V and either the sensitive immuno-transfer technique or immunoprecipitation from dodecylsulfate-solubilized mitochondria. In addition, a slight shoulder with a molecular mass 1.5 kDa larger than the mature form was present in mitochondria from the heme-deficient cells. Electron paramagnetic resonance spectroscopy revealed the absence of iron-sulfur signals due to clusters S-1, S-2 and S-3 of succinate dehydrogenase or to Rieske's iron-sulfur cluster of complex III in mitochondria from the heme-deficient cells. The lack of iron-sulfur centers in these cells may be a consequence of the absence of sulfite reductase in the cells without heme.     

Chloroplast ribosomal proteins of Chlamydomonas synthesized in the cytoplasm are made as precursors

Polyadenylated RNA from Chlamydomonas was translated in a cell-free rabbit reticulocyte system that employed [35S]methionine. Antibodies made to four chloroplast ribosomal proteins synthesized in the cytoplasm and imported into the organelle were used for indirect immunoprecipitation of the labeled translation products, which were subsequently visualized on fluorographs of SDS gels. The cytoplasmically synthesized chloroplast ribosomal proteins were first seen as precursors with apparent molecular weights of 1,000 to 6,000 greater than their respective mature forms. Processing of the ribosomal protein precursors to mature proteins was affected by adding a postribosomal supernatant that had been extracted from cells of Chlamydomonas. In contrast to the chloroplast ribosomal proteins synthesized in the cytoplasm, two such proteins made within the chloroplast were found to be synthesized in mature form in cell-free wheat germ translation systems programmed with nonpolyadenylated RNA.     

Cytochrome c oxidase from bakers' yeast. Photolabeling of subunits exposed to the lipid bilayer.

Yeast mitochondria and purified yeast cytochrome c oxidase incorporated into micelles of the nonionic detergent Tween 80 were equilibrated with the hydrophobic aryl azides 5-[125I]iodonaphthyl-1-azide or S-(4-azido-2-nitrophenyl)-[35S]thiophenol. The azides were then converted to highly reactive nitrenes by flash photolysis or by illumination for 2 min and the derivatized cytochrome c oxidase subunits were identified by gel electrophoresis and radioactivity measurements. 5-[125I]Iodonaphthyl-1-azide labeled mainly the three mitochondrially made Subunits I to III and the cytoplasmically made Subunit VII. Subunits IV to VI or cytochrome c bound to the purified enzyme were labeled 9- to 90-fold less. Essentially the same result was obtained with S-(4-azido-2-nitrophenyl)-[35S]thiophenol except that Subunit V was labeled as well. In contrast, all seven subunits as well as cytochrome c were heavily labeled when the enzyme was dissociated with dodecyl sulfate prior to photolabeling with either of the two probes. These data indicate that all subunits of yeast cytochrome c oxidase except Subunits IV and VI are at least partly embedded in the lipid bilayer of the mitochondrial inner membrane.     

Cytochrome b is necessary for the assembly of subunit VII in the cytochrome b-c1 complex of yeast mitochondria

The synthesis and assembly of subunit VII, the Q-binding protein of the cytochrome b-c1 complex, into the inner mitochondrial membrane has been compared in wild-type yeast cells and in a mutant cell line lacking cytochrome b. Both immunoblotting and immunoprecipitation analysis with specific antiserum against subunit VII indicated that this subunit is not detectable in the mutant as compared to the wild-type mitochondria. However, labeling in vivo of the cytochrome b deficient yeast cells in the presence of the uncoupler carbonyl cyanide m-chlorophenylhydrazone clearly demonstrated that subunit VII was synthesized in the mutant cells to the same extent as in the wild-type cells. Incubation of subunit VII, synthesized in vitro in a reticulocyte lysate programmed with yeast RNA, with mitochondria isolated from both wild-type and cytochrome b deficient yeast cells revealed that the subunit VII was transported into the wild-type mitochondria into a compartment where it was resistant to digestion by exogenous proteinase K. By contrast, subunit VII was bound in lowered amounts to the cytochrome b deficient mitochondria where it remained sensitive to digestion by exogenous proteinase K, suggesting that the import of subunit VII may be impaired due to the lack of cytochrome b. Furthermore, subunit VII was synthesized both in vivo and in vitro with the same molecular mass as the mature form of this protein.     

Early steps in assembly of the yeast vacuolar H+-ATPase.

Vacuolar proton-translocating ATPases are composed of a complex of integral membrane proteins, the Vo sector, attached to a complex of peripheral membrane proteins, the V1 sector. We have examined the early steps in biosynthesis of the yeast vacuolar ATPase by biosynthetically labeling wild-type and mutant cells for varied pulse and chase times and immunoprecipitating fully and partially assembled complexes under nondenaturing conditions. In wild-type cells, several V1 subunits and the 100-kDa Vo subunit associate within 3-5 min, followed by addition of other Vo subunits with time. Deletion mutants lacking single subunits of the enzyme show a variety of partial complexes, including both complexes that resemble intermediates in the assembly pathway of wild-type cells and independent V1 and Vo sectors that form without any apparent V1Vo subunit interaction. Two yeast sec mutants that show a temperature-conditional block in export from the endoplasmic reticulum accumulate a complex containing several V1 subunits and the 100-kDa Vo subunit during incubation at elevated temperature. This complex can assemble with the 17-kDa Vo subunit when the temperature block is reversed. We propose that assembly of the yeast V-ATPase can occur by two different pathways: a concerted assembly pathway involving early interactions between V1 and Vo subunits and an independent assembly pathway requiring full assembly of V1 and Vo sectors before combination of the two sectors. The data suggest that in wild-type cells, assembly occurs predominantly by the concerted assembly pathway, and V-ATPase complexes acquire the full complement of Vo subunits during or after exit from the endoplasmic reticulum.     

Efficient splicing of two yeast mitochondrial introns controlled by a nuclear-encoded maturase.

bI4 maturase encoded by the fourth intron of the yeast mitochondrial cytochrome b gene, controls the splicing of both the fourth intron of the cytochrome b gene and the fourth intron of the gene encoding subunit I of cytochrome oxidase. It has been shown previously that a cytoplasmically translated hybrid protein composed of the pre-sequence of subunit 9 of Neurospora ATPase fused to a part of the bI4 maturase can be guided to mitochondria where it could compensate maturase deficiencies. This in vivo complementation of maturase mutants can be easily estimated by restoration of respiration. This work examines the efficiency of different bI4 maturase constructions to restore respiration in different yeast maturase-deficient strains. It is shown that the N-terminal end of the bI4 maturase plays a crucial role in the maturase activity. Moreover, the 12 N-terminal amino acids of the mitochondrial outer membrane protein constitute the most efficient mitochondrial targeting sequence in this system. Surprisingly enough, it was found that the cytoplasmically translated bI4 maturase containing the 254 C-terminal amino acid coded by the intron open reading frame can complement maturase mutations without any added mitochondrial-targeting sequence.     

Further analysis of the polypeptide subunits of yeast cytochrome c oxidase. Isolation and characterization of subunits III, V, and VII

By using a modified purification procedure in which we have substituted detergent exchange gel filtration for DEAE-cellulose or hydroxylapatite chromatography (Mason, T. L., Poyton, R. O., Wharton, D. C., and Schatz, G. (1973) J. Biol. Chem. 248, 1346-1354), we have isolated yeast cytochrome c oxidase preparations which are low in contaminating polypeptides and which have been successfully used for the large scale purification of subunits. Subunits have been purified from this preparation by a simple two-step procedure which involves: 1) the release of subunits IV and VI from an "insoluble" core composed of subunits I, II, III, V, and VII; and 2) gel filtration of the "core" subunits in the presence of sodium dodecyl sulfate. Molecular weights of the isolated subunits, obtained from sodium dodecyl sulfate gel retardation coefficients (KR) derived from Ferguson plots, were: I, 54,000; II, 31,000; III, 29,500; IV, 14,500; V, 12,500; VI, 9,500; VII, 4,500. In their purified state all subunits, except for subunit V, exhibited electrophoretic behavior similar to that exhibited by unpurified subunits in sodium dodecyl sulfate-dissociated holoenzyme preparations. As purified, subunit V exhibits a slightly smaller apparent molecular weight than its counterpart in the holoenzyme. Amino acid analysis of the isolated subunits revealed that subunit III, a mitochondrial translation product, contained 41.9% polar amino acids, whereas subunits V and VII, cytoplasmic translation products, each contained 47.7% polar amino acids. These results extend and support our previous finding that the mitochondrially translated subunits of yeast cytochrome c oxidase are more hydrophobic than the cytoplasmically translated subunits.     

Import of proteins into mitochondria. The precursor of cytochrome c1 is processed in two steps, one of them heme-dependent

The apoprotein of yeast cytochrome c1 is made outside the mitochondria as a larger precursor which is then processed in at least two steps. In the first step, it is transported across both mitochondrial membranes and converted by a matrix-localized protease to an intermediate form whose molecular weight is between that of the precursor and the mature form. The intermediate form is bound to the outer face of the inner membrane. This first step requires an energized mitochondrial inner membrane, but no heme. In the second step, the intermediate form is converted to the mature cytochrome. This second step requires heme; it is blocked in a heme-deficient mutant or in wild type cells treated with an inhibitor of heme synthesis. Import of cytochrome c1 into mitochondria thus proceeds via two distinct heme-free precursors and at least two maturation steps, one of them dependent on heme.