Expression of modified cytochrome c1 genes and restoration of the respiratory function in a yeast mutant lacking the nuclear cytochrome c1 gene

Yeast cytochrome c1 is a component of complex III, an oligomeric enzyme of the mitochondrial respiratory chain. In order to investigate the structural requirement of cytochrome c1 for the function and assembly of the enzyme, we used an in vivo complementation assay to determine whether or not an in vitro mutated cytochrome c1 is functional. A yeast mutant whose nuclear cytochrome c1 gene was specifically inactivated was constructed by means of a gene disruption technique. The mutant was unable to respire, and lacked spectrally and immunochemically detectable cytochrome c1. These defects disappeared on the introduction of a plasmid carrying the cytochrome c1 gene coding the wild-type molecule or one coding a mutant molecule lacking the carboxyl (C)-terminal 17 amino acid residues. On the other hand, another mutant gene with a deletion corresponding to the C-terminal 71 residues showed no such ability. These results suggest that the region between the C-terminal 17 and 71 residues is necessary for the function of cytochrome c1.     

The C-terminal half of the 11-kDa subunit VIII is not necessary for the enzymic activity of yeast ubiquinol:cytochrome-c oxidoreductase

Inactivation of the gene encoding the 11-kDa subunit VIII of yeast ubiquinol:cytochrome c oxidoreductase leads to an inactive complex, which lacks detectable cytochrome b [Maarse, A. C., De Haan, M., Schoppink, P. J., Berden, J. A. and Grivell, L. A. (1988) Eur. J. Biochem. 172, 179-184] and in which the steady-state levels of the Fe-S protein and the 14-kDa subunit VII are severely reduced. When the 11-kDao mutant is transformed with a gene encoding a protein consisting of the 11-kDa protein minus its last 11 amino acids and fused to a 7-amino-acid sequence encoded by a stop oligonucleotide, the complex is assembled normally. Enzyme activity is similar to that of the wild type, as is also the sensitivity of the complex to antimycin and myxothiazol. Transformation of the mutant with a gene encoding a protein consisting of the 11-kDa protein lacking the last 43 amino acids (i.e. almost half the protein) and fused to the same 7-amino-acid sequence as above, gives partial restoration of the complex. The Fe-S protein and the 14-kDa subunit VII still exhibit low steady-state levels, but cytochrome b is present again, albeit at a strongly reduced level. Electron transport activity is also partially restored and correlates with the level of cytochrome b indicating that the turnover number of the complex is similar to that of wild-type complex III. These findings demonstrate the important role played by the 11-kDa protein in the stabilization of cytochrome b. They also imply that at least the C-terminal half of the 11-kDa protein is not part of an ubiquinol-binding site. Moreover, since the deletion has no effect on the sensitivity of the complex to myxothiazol and antimycin, at least this part of the protein is probably not involved in binding of these inhibitors.     

The effect of deletion of the genes encoding the 40 kDa subunit II or the 17 kDa subunit VI on the steady-state kinetics of yeast ubiquinol-cytochrome-c oxidoreductase

Yeast ubiquinol-cytochrome c oxidoreductase is still active after inactivation of the genes encoding the 40 kDa Core II protein or the 17 kDa subunit VI (Oudshoorn et al. (1987) Eur. J. Biochem. 163, 97-103 and Schoppink et al. (1988) Eur. J. Biochem. 173, 115-122). The steady-state levels of several other subunits of Complex III are severely reduced in the 40 kDa0 mutant. The level of spectrally detectable Complex III cytochrome b in the mutant submitochondrial particles is about 5% of that of the wild type. However, when the steady-state activity of Complex III with respect to the cytochrome c reduction was examined, similar maximal turnover numbers and Km values were found for the mutated and the wild-type complexes, both when yeast cytochrome c and when horse-heart cytochrome c was used as electron acceptor. We therefore conclude that the Core II subunit of yeast Complex III plays no role in the binding of cytochrome c and that it has no major influence of the overall electron transport and on the binding of ubiquinol by the enzyme. Absence of the 17 kDa subunit VI of yeast Complex III, the homologous counterpart of the hinge protein of the bovine heart enzyme, resulted in a decrease in the rate of reduction of both horse-heart cytochrome c and yeast cytochrome c by Complex III under conditions of relatively high ionic strength. However, under conditions of optimal ionic strength, no difference could be seen in the maximal turnover numbers and Km values, neither with horse-heart cytochrome c nor with yeast cytochrome c between Complex III deficient in the 17 kDa protein and the wild-type complex. Binding of ATP to ferricytochrome c inhibits its reduction by Complex III under conditions of relatively high ionic strength. But when the 17 kDa protein is absent, this inhibition is also observed under optimal ionic-strength conditions. These results can be explained by assuming a stimulating role for the acidic 17 kDa protein in the association of basic cytochrome c with Complex III. This association is (part of) the rate-limiting step in the reduction of cytochrome c by Complex III under conditions of relatively high ionic strength or when this association is hindered, for instance, by binding of ATP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Disruption of the gene encoding subunit VI of yeast cytochrome bc1 complex causes respiratory deficiency of cells with reduced cytochrome c levels

A double mutant of Saccharomyces cerevisiae, in which CYCL gene is deleted and the chromosomal copy of the 17 kDa protein gene is disrupted, has been constructed. This mutant cannot grow on nonfermentable carbon sources, but normal growth can be restored by complementation of either mutation with a yeast vector containing either the wild-type 17 kDa protein gene or the CYCl gene. These results show that although the 17 kDa protein, subunit VI of yeast cytochrome bc1 complex is dispensable for yeast mitochondrial respiration in cells with the wild-type levels of cytochrome c, the 17 kDa protein is essential for respiration when the level of cytochrome c is limited, indicating that is plays a role in electron transport. This glycerol- phenotype of the double mutant can serve as the basis for further genetic studies on the function of the 17 kDa protein in yeast mitochondria and may provide insight into the physiological function of the hinge protein, the counterpart of the yeast 17 kDa protein, in beef heart mitochondria.     

Deletion of the 6-kDa subunit affects the activity and yield of the bc1 complex from Rhodovulum sulfidophilum.

The cytochrome bc1 complex from Rhodovulum sulfidophilum purifies as a four-subunit complex: the cytochrome b, cytochrome c1 and Rieske iron-sulphur proteins, which are encoded together in the fbc operon, as well as a 6-kDa protein. The gene encoding the 6-kDa protein, named fbcS, has been identified. It is located within the sox operon, which encodes the subunits of sarcosine oxidase. The encoded 6-kDa protein is very hydrophobic and is predicted to form a single transmembrane helix. It shows no sequence homology to any known protein. The gene has been knocked-out of the genome and a three-subunit complex can be purified. This deletion leads to a large reduction in the yield of the isolated complex and in its activity compared to wild-type. The high quinone content found in the wild-type complex is, however, maintained after removal of the 6-kDa protein. Surprisingly, a fourth subunit of approximately 6 kDa is again found to copurify with the Rhv. sulfidophilum bc1 complex when only the fbc operon is expressed heterologously in a near-relative, Rhodobacter capsulatus, which lacks this small subunit in its own bc1 complex.     

Isolation and characterization of QCR9, a nuclear gene encoding the 7.3-kDa subunit 9 of the Saccharomyces cerevisiae ubiquinol-cytochrome c oxidoreductase complex. An intron-containing gene with a conserved sequence occurring in the intron of COX4

A nuclear gene (QCR9) encoding the 7.3-kDa subunit 9 of the mitochondrial cytochrome bc1 complex from Saccharomyces cerevisiae has been isolated from a yeast genomic library by hybridization with a degenerate oligonucleotide corresponding to nine amino acids proximal to the N terminus of purified subunit 9. QCR9 includes a 195-base pair open reading frame capable of encoding a protein of 66 amino acids and having a predicted molecular weight of 7471. The N-terminal methionine of subunit 9 is removed posttranslationally because the N-terminal sequence of the purified protein begins with serine 2. The ATG triplet corresponding to the N-terminal methionine is separated from the open reading frame by an intron. The intron is 213 base pairs long and contains previously reported 5' donor, 3' acceptor, and TACTAAC sequences necessary for splicing. The splice junctions, as well as the 5' end of the message, were confirmed by isolation and sequencing of a cDNA copy of QCR9. In addition, the intron contains a nucleotide sequence in which 15 out of 18 nucleotides are identical with a sequence in the intron of COX4, the nuclear gene encoding cytochrome c oxidase subunit 4. The deduced amino acid sequence of the yeast subunit 9 is 39% identical with that of a protein of similar molecular weight from beef heart cytochrome bc1 complex. If conservative substitutions are allowed for, the two proteins are 56% similar. The predicted secondary structure of the 7.3-kDa protein revealed a single possible transmembrane helix, in which the amino acids conserved between beef heart and yeast are asymmetrically arranged along one face of the helix, implying that this domain of the protein is involved in a conserved interaction with another hydrophobic protein of the cytochrome bc1 complex. Two yeast strains, JDP1 and JDP2, were constructed in which QCR9 was deleted. Both strains grew very poorly, or not at all, on nonfermentable carbon sources and exhibited, at most, only 5% of wild-type ubiquinol-cytochrome c oxidoreductase activity. Optical spectra of mitochondrial membranes from the deletion strains revealed slightly reduced levels of cytochrome b. When JDP1 and JDP2 were complemented with a plasmid carrying QCR9, the resulting yeast grew normally on ethanol/glycerol and exhibited normal cytochrome c reductase activities and optical spectra. These results indicate that QCR9 encodes a 7.3-kDa subunit of the bc1 complex that is required for formation of a fully functional complex.(ABSTRACT TRUNCATED AT 400 WORDS)     

Biosynthesis of the ubiquinol-cytochrome c reductase complex in yeast. Characterization of precursor forms of the 44-kDa, 40-kDa and 17-kDa subunits and identification of individual messenger RNAs for these and other imported subunits of the complex

The mitochondrial ubiquinol--cytochrome c reductase complex (complex III or cytochrome bc1 complex) is thought to consist of eight subunits, seven of which are specified by nuclear genes and synthesized in the cytoplasm. We have studied the synthesis of five of the nuclear-encoded subunits both in vivo and in vitro and show that of these the 44-kDa, 40-kDa and 17-kDa subunits are synthesized with cleavable extensions, while the 14-kDa and 11-kDa proteins are synthesized without detectable extra sequences. The sizes of the pre-sequences, as determined by the relative mobility of the precursor proteins in sodium dodecyl sulphate/polyacrylamide gels, range from 0.5-kDa for the 44-kDa and 40-kDa subunits to 9-kDa for the 17-kDa subunit. The existence in vivo of precursor forms to the 44-kDa, 40-kDa and 17-kDa subunits implies that import is at least partially a post-translational process. The precursor of the 44-kDa subunit can be processed post-translationally in vitro by isolated mitochondria. The messenger RNAs for subunits of the complex have been studied. Those coding for the 44-kDa, 40-kDa, 14-kDa and 11-kDa proteins and cytochrome c1 are of different sizes, indicating that each of these subunits is synthesized as a separate protein, rather than as part of a polyprotein precursor.     

Transformation in Bacillus subtilis: involvement of the 17-kilodalton DNA-entry nuclease and the competence-specific 18-kilodalton protein.

A protein complex, consisting of a 17-kilodalton (kDa) nuclease and an 18-kDa protein, is believed to be involved in the binding and entry of donor DNA during transformation of Bacillus subtilis (H. Smith, K. Wiersman, S. Bron, and G. Venema, J. Bacteriol. 156:101-108, 1983). In this paper, the nucleotide sequences of the genes encoding both the nuclease and the 18-kDa protein are presented. The genes are encoded by a 904-base-pair PstI-HindIII fragment. The open reading frames encoding both proteins are partly overlapping. A B. subtilis mutant was constructed by insertion of a Cmr marker into the gene encoding the nuclease. This mutant lacked the competence-specific nuclease activity and the 18-kDa protein but retained 5% residual transformation. The total DNA association of the mutant was higher than that of the wild-type cells, and DNA entry was reduced to 30% of the wild-type level. These results suggest that an alternative pathway exists for the internalization of transforming DNA. A mutant, exclusively deficient for the 18-kDa protein, previously suggested to be involved in the binding of transforming DNA, was constructed by insertion of a kanamycin resistance gene into the coding sequence of the gene. Since the mutant showed wild-type DNA-binding activity, the 18-kDa protein is probably not involved in the binding of donor DNA to competent cells. The transforming activity of the mutant was reduced to 25% of the wild-type level, indicating that the 18-kDa protein has a function in the transformation process. In vitro experiments showed that the 18-kDa protein is capable of inhibiting the activity of the competence-specific nuclease. Its possible role in transformation is discussed.     

The role of the MxaD protein in the respiratory chain of Methylobacterium extorquens during growth on methanol

The largest of the gene clusters coding for proteins involved in methanol oxidation is the cluster mxaFJGIR(S)ACKLDEHB. Disruption of most of these genes leads to lack of growth on methanol. The previous results showed that the mutant lacking MxaD grows on methanol although at a low rate. This is explained by the low rate of methanol oxidation by whole cells. The specific activity of methanol dehydrogenase (MDH) is higher in the mutant but its electron acceptor (cytochrome c(L)) is unchanged. Using the purified proteins, it was shown that the rate of interaction of MDH and cytochrome c(L) was higher in the wild-type MDH containing some MxaD proteins, which was absent in the mutant MDH. It is suggested that the gene mxaD codes for the 17-kDa periplasmic protein that directly or indirectly stimulates the interaction between MDH and cytochrome c(L); its absence leads to a lower rate of respiration with methanol and therefore a lower growth rate on this substrate.     

The 24-kDa iron-sulphur subunit of complex I is required for enzyme activity.

We have cloned the nuclear gene encoding the 24-kDa iron-sulphur subunit of complex I from Neurospora crassa. The gene was inactivated in vivo by repeat-induced point-mutations, and mutant strains lacking the 24-kDa protein were isolated. Mutant nuo24 appears to assemble an almost intact complex I only lacking the 24-kDa subunit. However, we also found reduced levels of the NADH-binding, 51-kDa subunit of the enzyme. Surprisingly, the complex I from the nuo24 strain lacks NADH:ferricyanide reductase activity. In agreement with this, the respiration of intact mitochondria or mitochondrial membranes from the mutant strain is insensitive to rotenone inhibition. These results suggest that the nuo24 complex is not functioning in electron transfer and the 24-kDa protein is absolutely required for complex I activity. This phenotype may explain the findings that the 24-kDa iron-sulphur protein is reduced or absent in human mitochondrial diseases. In addition, selected substitutions of cysteine to alanine residues in the 24-kDa protein suggest that binding of the iron-sulphur centre is a requisite for protein assembly.     

Yeast cytochrome c oxidase subunit VII is essential for assembly of an active enzyme. Cloning, sequencing, and characterization of the nuclear-encoded gene

The gene COX VII coding for yeast cytochrome c oxidase subunit VII has been cloned by a two-step procedure. Two degenerate oligonucleotides corresponding to amino- and carboxyl-terminal protein segments were used in a polymerase chain reaction for the amplification of a major portion of subunit VII (residues 1-52), which was then used for the cloning of complete COX VII. From the nucleotide sequence, an additional amino-terminal and two additional carboxyl-terminal amino acids are predicted as compared with the described primary sequence (Power, S. D., Lochrie, M. A., and Poyton, R. O. (1986) J. Biol. Chem. 261, 9206-9209). Beside subunit VIIa the subunit described here is the only nuclear encoded subunit of cytochrome c oxidase in yeast without a leader sequence. COX VII exists as a single copy per haploid genome as shown by Southern blot and gene disruption. Null mutants produced by gene disruption at the COX VII locus were respiratory-deficient. No cytochrome c oxidase activity was detectable nor was there an assembly of the oxidase complex.     

The cytoplasmically-made subunit IV is necessary for assembly of cytochrome c oxidase in yeast.

Yeast cytochrome c oxidase contains three large subunits made in mitochondria and at least six smaller subunits made in the cytoplasm. There is evidence that the catalytic centers (heme a and copper) are associated with the mitochondrially-made subunits, but the role of the cytoplasmically-made subunits has remained open. Using a gene interruption technique, we have now constructed a Saccharomyces cerevisiae mutant which lacks the largest of the cytoplasmically-made subunits (subunit IV). This mutant is devoid of cyanide-sensitive respiration, the absorption spectrum of cytochrome aa3 and cytochrome c oxidase activity. It still contains the other cytochrome c oxidase subunits but these are not assembled into a stable complex. Active cytochrome c oxidase was restored to the mutant by introducing a plasmid-borne wild-type subunit IV gene; no restoration was seen with a gene carrying an internal deletion corresponding to amino acid residues 28-66 of the mature subunit. Subunit IV is thus necessary for proper assembly of cytochrome c oxidase.     

Assembly of the mitochondrial membrane system. Characterization of COR1, the structural gene for the 44-kilodalton core protein of yeast coenzyme QH2-cytochrome c reductase

The respiratory deficiency of yeast strains previously assigned to complementation group G7 has been ascribed to the absence in the mutants of functional cytochrome b. Since G7 mutants are capable of synthesizing the apoprotein, the primary effect of the mutations is to prevent maturation of this electron carrier. The recombinant plasmid pG7/T1 with a 6.7-kilobase pairs (kb) insert of wild type yeast nuclear DNA has been selected from a genomic library by transformation of a G7 mutant to respiratory competency. The genetically active region of the pG7/T1 insert has been subcloned on a 3-kb fragment of DNA which has been shown to contain an open reading frame encoding a protein of 50,236 Mr. In situ disruption of the reading frame causes a deficiency in cytochrome b. The strain with the disrupted gene fails to complement G7 mutants thereby confirming the correct identification of the gene henceforth referred to as COR1. The carboxyl-terminal half of the COR1 gene has been fused to the amino-terminal half of the Escherichia coli trpE gene in the high expression vector pATH2. This plasmid construct promotes a high level of expression of the trpE/COR1 hybrid protein. Antibodies against the purified hybrid protein react with a 44 kDa protein subunit of yeast coenzyme QH2-cytochrome c reductase corresponding to the largest core subunit of the complex. These data indicate that the yeast nuclear gene COR1 codes for the 44-kDa core protein and that the latter is required for the conversion of apocytochrome b to mature cytochrome b.     

Molecular analysis of the cytochrome bc 1-aa 3 branch of the Corynebacterium glutamicum respiratory chain containing an unusual diheme cytochrome c 1

In this work, the genes for cytochrome aa3 oxidase and the cytochrome bc1 complex in the gram-positive soil bacterium Corynebacterium glutamicum were identified. The monocistronic ctaD gene encoded a 65-kDa protein with all features typical for subunit I of cytochrome aa3 oxidases. A ctaD deletion mutant lacked the characteristic 600 nm peak in redox difference spectra, and growth in glucose minimal medium was strongly impaired. The genes encoding subunit III of cytochrome aa3 (ctaE) and the three characteristic subunits of the cytochrome bc1 complex (qcrABC) were clustered in the order ctaE-qcrCAB. Analysis of the deduced primary structures revealed a number of unusual features: (1) cytochrome c1 (QcrC, 30 kDa) contained two Cys-X-X-Cys-His motifs for covalent heme attachment, indicating that it is a diheme c-type cytochrome; (2) the 'Rieske' iron-sulphur protein (QcrA, 45 kDa) contained three putative transmembrane helices in the N-terminal region rather than only one; and (3) cytochrome b (QcrB, 60 kDa) contained, in addition to the conserved part with eight transmembrane helices, a C-terminal extension of about 120 amino acids, which presumably is located in the cytoplasm. Staining of C. glutamicum proteins for covalently bound heme indicated the presence of a single, membrane-bound c-type cytochrome with an apparent molecular mass of about 31 kDa. Since this protein was missing in a qcrCAB deletion mutant, it most likely corresponds to cytochrome c1. Similar to the deltactaD mutant, the deltaqcrCAB mutant showed strongly impaired growth in glucose minimal medium, which indicates that the bc1-aa3 pathway is the main route of respiration under these conditions.     

One nuclear gene controls the removal of transient pre-sequences from two yeast proteins: one encoded by the nuclear the other by the mitochondrial genome.

The proteolytic processing of the mitochondrially encoded subunit II of cytochrome oxidase is prevented by the yeast mutation ts2858. We report that the mutant is, in addition, temperature sensitive for the processing of cytochrome b2, a protein encoded by nuclear DNA. Thus the same mutation affects the removal of pre-sequences from a mitochondrially encoded inner membrane protein and from an imported soluble protein located in the intermembrane space. The mutation blocks the second processing step of cytochrome b2. The cytochrome b2 intermediate accumulates in the mutant at 36 degrees C and assumes its enzyme activity. At 23 degrees C the conversion to the mature protein is considerably slower than in wild-type cells. The similarity of the cleavage sites Asn-Asp and Asn-Glu of the precursors for cytochrome oxidase subunit II and cytochrome b2, respectively, suggests a sequence-specific recognition by one protease or a factor activating a protease. On the other hand maturation of cytochrome c peroxidase, another enzyme of the intermembrane space, is not affected by the pet ts2858 mutation.     

Deletion of the COX7 gene in Saccharomyces cerevisiae reveals a role for cytochrome c oxidase subunit VII In assembly of remaining subunits

Cytochrome c oxidase from Saccharomyces cerevisiae is composed of nine subunits. Subunits I, II and III are products of mitochondrial genes, while subunits IV, V, VI, VII, VIIa and VIII are products of nuclear genes. To investigate the role of cytochrome c oxidase subunit VII in biogenesis or functioning of the active enzyme complex, a null mutation in the COX7 gene, which encodes subunit VII, was generated, and the resulting cox7 mutant strain was characterized. The strain lacked cytochrome c oxidase activity and haem a/a3 spectra. The strain also lacked subunit VII, which should not be synthesized owing to the nature of the cox7 mutation generated in this strain. The amounts of remaining cytochrome c oxidase subunits in the cox7 mutant were examined. Accumulation of subunit I, which is the product of the mitochondrial COX1 gene, was found to be decreased relative to other mitochondrial translation products. Results of pulse-chase analysis of mitochondrial translation products are consistent with either a decreased rate of translation of COX1 mRNA or a very rapid rate of degradation of nascent subunit I. The synthesis, stability or mitochondrial localization of the remaining nuclear-encoded cytochrome c oxidase subunits were not substantially affected by the absence of subunit VII. To investigate whether assembly of any of the remaining cytochrome c oxidase subunits is impaired in the mutant strain, the association of the mitochondrial-encoded subunits I, II and III with the nuclear-encoded subunit IV was investigated.(ABSTRACT TRUNCATED AT 250 WORDS)     

A pathogenic 15-base pair deletion in mitochondrial DNA-encoded cytochrome c oxidase subunit III results in the absence of functional cytochrome c oxidase

A 15-base pair, in-frame, deletion (9480del15) in the mitochondrial DNA (mtDNA)-encoded cytochrome c oxidase subunit III (COX III) gene was identified previously in a patient with recurrent episodes of myoglobinuria and an isolated COX deficiency. Transmitochondrial cell lines harboring 0, 97, and 100% of the 9480del15 deletion were created by fusing human cells lacking mtDNA (rho(0) cells) with platelet and lymphocyte fractions isolated from the patient. The COX III gene mutation resulted in a severe respiratory chain defect in all mutant cell lines. Cells homoplasmic for the mutation had no detectable COX activity or respiratory ATP synthesis, and required uridine and pyruvate supplementation for growth, a phenotype similar to rho(0) cells. The cells with 97% mutated mtDNA exhibited severe reductions in both COX activity (6% of wild-type levels) and rates of ATP synthesis (9% of wild-type). The COX III polypeptide in the mutant cells, although translated at rates similar to wild-type, had reduced stability. There was no evidence for assembly of COX I, COX II, or COX III subunits in a multisubunit complex in cells homoplasmic for the mutation, thus indicating that there was no stable assembly of COX I with COX II in the absence of wild-type COX III. In contrast, the COX I and COX II subunits were assembled in cells with 97% mutated mtDNA.     

Mitochondrial membrane biogenesis: characterization and use of pet mutants to clone the nuclear gene coding for subunit V of yeast cytochrome c oxidase

A nuclear pet mutant of Saccharomyces cerevisiae that is defective in the structural gene for subunit V of cytochrome c oxidase has been identified and used to clone the subunit V gene (COX5) by complementation. This mutant, E4-238 [24], and its revertant, JM110, produce variant forms of subunit V. In comparison to the wild-type polypeptide (Mr = 12,500), the polypeptides from E4-238 and JM110 have apparent molecular weights of 9,500 and 13,500, respectively. These mutations directly alter the subunit V structural gene rather than a gene required for posttranslational processing or modification of subunit V because they are cis-acting in diploid cells; that is, both parental forms of subunit V are produced in heteroallelic diploids formed from crosses between the mutant, revertant, and wild type. Several plasmids containing the COX5 gene were isolated by transformation of JM28, a derivative of E4-238, with DNA from a yeast nuclear DNA library in the vector YEp13. One plasmid, YEp13-511, with a DNA insert of 4.8 kilobases, was characterized in detail. It restores respiratory competency and cytochrome oxidase activity in JM28, encodes a new form of subunit V that is functionally assembled into mitochondria, and is capable of selecting mRNA for subunit V. The availability of mutants altered in the structural gene for subunit V (COX5) and of the COX5 gene on a plasmid, together with the demonstration that plasmid-encoded subunit V is able to assemble into a functional holocytochrome c oxidase, enables molecular genetic studies of subunit V assembly into mitochondria and holocytochrome c oxidase.     

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.