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.     

Studies on the assembly of cytochrome oxidase in isolated rat hepatocytes.

1. The assembly of rat liver cytochrome oxidase was studied in isolated hepatocytes and isolated liver mitochondria labelled with L-[35S]methionine. 2. Labelled subunits II and III appeared in the immunoabsorbed holoenzyme within minutes after the initiation of a pulse label. In contrast, labelled subunit I appeared in immunoabsorbed holoenzyme only after a subsequent 2 h chase or after an additional 2 h of labelling. Subunit I was heavily labelled, however, in intact mitochondria after 10 min. 3. A similar pattern of labelling was observed in holo-cytochrome oxidase which was chemically isolated by a small scale procedure adapted for this purpose. The appearance of subunit I in the holoenzyme was delayed for 1.5-2 h after a 60 min pulse with labelled methionine. 4. Incubation of hepatocytes for 4 h in the presence of cycloheximide had no effect on the labelling pattern described above. 5. Methods were developed in which newly translated, presumably unassembled, subunits of cytochrome oxidase could be separated from the holoenzyme by fractionation in Triton X-114. Short-term pulse experiments indicate that subunits II and III are associated with the holoenzyme fraction immediately after their completion, whereas subunit I is not. 6. The data are consistent with a model in which cytochrome oxidase assembly is viewed as an ordered and sequential event.     

Interaction of prostaglandin E1 with human high density lipoproteins

The assembly of cytochrome c oxidase subunits I-III was studied in vitro in isolated rat liver mitochondria pre-labeled with [35S]methionine. Individual subunits were immunoabsorbed with monospecific antibodies. Isolated heme a from rat liver mitochondria, when added to radiolabeled mitochondria, induced assembly of subunit I with subunits II and III. Assembly of these subunits was not observed in mitochondria incubated in the presence of heme b(hemin) or in the absence of heme. Quantitative analysis of immunoabsorbed, radiolabeled subunits suggests that the predominant effect of heme a is on the assembly of subunit I with subunit III.     

Immunoprecipitation of a cytoplasmic precursor of rat-liver cytochrome oxidase.

A simple method for the isolation of rat liver cells is described. The cells are shown, by an isotope dilution method, to maintain a constant rate of protein synthesis for 8 h of incubation. Antibodies to purified rat liver cytochrome oxidase were raised in rabbits and used to investigate the labeling of cytochrome oxidase in isolated rat liver cells and in vivo. The data demonstrate the occurrence of a precursor of the subunits of cytochrome oxidase that are synthesized in the cytoplasm. 1. Dodecylsulfate gel electrophoresis of the immunoprecipitates from isolated rat liver cells that had been labeled with [35S]methionine for 1 h showed a single radioactive peak with a molecular weight of 50000. 2. Judged by the effects of cycloheximide and chloramphenicol the labeled protein is synthesized on cytoplasmic ribosomes. 3. After labeling for 1 h in vivo with [3H]leucine the labeled protein appears to be exclusively associated with the hepatic microsomal fraction. 4. Ouchterlony double-diffusion analysis demonstrated immunological relationship between the precipitates from microsomes and cytochrome oxidase. In addition to the precipitates derived from mitochondria and microsomes immunoprecipitates were also obtained from the cytosol in comparable amounts; these again were immunologically related. The occurrence of large amounts of precursor(s) (or degradation products) of cytochrome oxidase in rat liver fractions is interpreted in terms of a regulatory pool for amino acid homeostasis in the organism.     

Labeling of cytochrome c oxidase with [35S]diazobenzenesulfonate. Orientation of this electron transfer complex in the inner mitochondrial membrane.

Isolated cytochrome c oxidase was fractionated by native-gel electrophoresis in Triton X-100, and a preparation of enzyme almost completely free of the usual impurities was recovered. This fraction was used to generate antibodies specific to cytochrome c oxidase. These antibodies inhibited cytochrome c oxidase activity rapidly and completely and immunoprecipitated an enzyme containing seven different subunits from detergent-solubilized mitochondria or submitochondrial particles. Reaction of detergent-solubilized cytochrome c oxidase with [35S]diazobenzenesulfonate labeled all seven subunits although I and VI were much less reactive than the other five components. When cytochrome c oxidase was immunoprecipitated from mitochondria which had been reacted with [35S]DABS, subunits II and III were the only components labeled. When the complex was immunoprecipitated from labeled submitochondrial particles, II, III, IV, V, and VII were all labeled. Polypeptides I and VI were not labeled from either side of the membrane. These results confirm earlier studies which showed that cytochrome c oxidase spans the mitochondrial inner membrane and is asymmetrically arranged across this permeability barrier.     

Arrangement of the subunits in solubilized and membrane-bound cytochrome c oxidase from bovine heart.

The arrangement of the six cytochrome c oxidase subunits in the inner membrane of bovine heart mitochondria was investigated. The experiments were carried out in three steps. In the first step, exposed subunits were coupled to the membrane-impermeant reagent p-diazonium benzene [32S]sulfonate. In the second step, the membranes were lysed with cholate anc cytochrome c oxidase was isolated by immunoprecipitation. In the third step, the six cytochrome c oxidase subunits were separated from each other by dodecyl sulfate-acrylamide gel electrophoresis and scanned for radioactivity. Exposed subunits on the outer side of the mitochondrial inner membrane were identified by labeling intact mitochondria. Exposed subunits on the matrix side of the inner membrane were identified by labeling sonically prepared submitochondrial particles in which the matrix side of the inner membrane is exposed to the suspending medium. Since sonic irradiation leads to a rearrangement of cytochrome c oxidase in a large fraction of the resulting submitochondrial particles, an immunochemical procedure was developed for isolating particles with a low content of displaced cytochrome c oxidase. With mitochondria, subunits II, V, and VI were labeled, whereas in purified submitochondrial particles most of the label was in subunit III. The arrangement of cytochrome c oxidase in the mitochondrial inner membrane is thus transmembraneous and asymmetric; subunits II, V, and VI are situated on the outer side, subunit III is situated on the matrix side, and subunits I and IV are buried in the interior of the membrane. In a study of purified cytochrome c oxidase labeled with p-diazonium benzene [32S]sulfonate, the results were similar to those obtained with the membrane-bound enzyme. Subunits I and IV were inaccessible to the reagent, whereas the other four subunits were accessible. In contrast, all six subunits became labeled if the enzyme was dissociated with dodecyl sulfate before being exposed to the labeling reagent.     

Comparative study of the peptide composition of Complex III (quinol-cytochromec reductase)

A comparative study has been made on the subunits of Complex III from beef heart, rat liver, Neurospora, and baker's yeast mitochondria. All of the subunits of the beef heart enzyme were similar to the counterpart subunit in rat liver Complex III, both with respect to their apparent molecular weights on SDS-polyacrylamide gels and their proteolytic digestion maps obtained in the presence of S. subtilus V8 protease. In contrast, the subunits of Neurospora and yeast Complex III varied considerably from the mammalian enzyme, as well as between themselves, the only exception being cytochrome b (subunit III). Less variation was observed in the electron transport peptides (IV-V) of higher and lower eukaryotes than in those subunits (I, II, VI-VIII) for which no functions are known. However, the data imply that subunits I, II, and VI-VIII are bona fide members of the complex, and that their functions within the complex, although unknown, are also somewhat conserved. Finally, the low-molecular-weight subunits of rat liver cytochrome oxidase and Complex III were compared. They appear to contain no subunits in common, implying different roles for these peptides in the two complexes.     

Proteolytic precursor processing in the biosynthesis of mitochondria

Essentially all polypeptides synthesized in the cytoplasm and imported into either the matrix or into the inner or outer membrane of mitochondria are made as larger molecular weight precursors. All known examples of in vivo or in vitro synthesized precursors are summarized. Little information on the nature of the proteolytic enzymes involved in the processing of the larger precursor polypeptides exists. The biosynthesis of rat liver cytochrome c oxidase is discussed in detail. In contrast to reported data, the cytoplasmic subunits of rat liver cytochrome c oxidase are synthesized as larger molecular weight precursors and not as a polyprotein. Precursors to subunits IV and V show an extra-peptide sequence of about 3000 daltons. Evidence against the existence of a polyprotein precursor was also obtained, when messenger RNAs for the individual subunits IV and V were isolated and analyzed in respect to their size. A length of 990 +/- 80 and 830 +/- 70 nucleotides was estimated for the poly(A)+-RNA of cytochrome c oxidase subunits IV and V, respectively. In experiments on the site of synthesis, it was found that cytochrome c oxidase subunits IV and V are made on free, loosely and tightly membrane-bound polyribosomes.     

On the molecular weight of mitochondrially synthesized subunits of rat liver cytochrome oxidase.

The subunit composition of cytochrome c oxidase from rat liver mitochondria was studied by dodecylsulfate polyacrylamide gel electrophoresis. The apparent molecular weight of the seven subunits are in reasonable agreement with published data on cytochrome c oxidase subunits from other sources. Two additional subunits were found if the electrophoresis was performed with 8m urea, due to splitting of the smallest subunit. Performic acid oxidation of the isolated subunits I and II increased the apparent molecular weights from 38000 to 48000 and from 24500 to 29000, respectively, accompained by a normalization of the anomalous behaviour of subunit I in the Ferguson plot. It is suggested that performic acid, by splitting extremely inaccessible disulfide bridges, mediates full complexing of the subunits by dodecylsulfate, thus permitting the determination of the real molecular weights by dodecylsulfate polyacrylamide gel electrophoresis.     

Immunological studies on cytochrome c oxidase: arrangements of protein subunits in the solubilized and membrane-bound enzyme.

Seven protein subunits of cytochrome c oxidase from bovine heart were isolated by gel filtration in the presence of sodium dodecyl sulphate (subunits I, II and III) and guanidine hydrochloride (subunits V, VI and VII), and ion-exchange chromatography in 6 M urea (subunit IV) after the enzyme had been dissociated in 6 M guanidine hydrochloride. When analysed by highly cross-linked sodium dodecyl sulphate/polyacrylamide gel electrophoresis in the presence of urea, the apparent molecular weights were = I, 36700; II, 24300; III, 20400; IV, 17300; V, 12300; VI, 8700: and VII, 5100. Monospecific rabbit antisera were obtained against subunits I, IV, V, VI and VII and a mixture of subunits II and III. These subunit-specific antisera with the exception of anti-I serum all cross-reacted with the detergent-solubilized native oxidase. Enzymatic studies on purified oxidase indicated that immunoglobulins against subunits II + III, IV, V, VI and VII respectively caused 25, 65, 20, 30 and 25% inhibition while anti-I immunoglobulin did not inhibit the activity. The subunit-specific antisera were used to examine the arrangements of the subunits in the membrane. Enzymatic studies using bovine heart mitochondria and rat liver mitochondrial digitonin particles showed that anti-(II + III) serum, anti-V serum and anti-VII serum all inhibited the oxidase activity while the other antisera did not. On the other hand, results of using 125I-labelled immunoglobulins showed that anti-IV, anti-V and anti-VII sera were bound to the surface of inverted vesicles (matrix side) while all other antisera were not. These results indicate that cytochrome oxidase subunits II and III are situated on the outer surface, and subunit IV is exclusively on the matrix surface while subunits V and VII are exposed on both surfaces of the mitochondrial membrane. Subunits I and VI are buried within the membrane, not exposed on either side.     

Three subunit proteins of membrane enzymes in mitochondria of Neurospora crassa contain a pantothenate derivative

Three proteins of the inner mitochondrial membrane of Neurospora crassa were found to be covalently modified with a derivative of pantothenic acid. One of these proteins is a subunit of cytochrome c oxidase and two are subunits of the ATPase-ATP synthase. Cells of a pantothenate auxotroph of N. crassa were labeled with [14C]pantothenic acid, and mitochondrial proteins containing radiolabeled pantothenate were detected by electrophoresis of detergent-solubilized mitochondria. Mitochondria from cells that were colabeled with [14C]pantothenate and [3H]leucine were reacted with specific antisera against the cytochrome c oxidase and F1-ATPase enzyme complexes. Electrophoresis of the labeled subunits of these isolated complexes showed that the [14C]pantothenate-associated peptides corresponded to [3H]leucine-labeled subunit 6 of cytochrome c oxidase and two [3H]leucine-labeled subunits (tentatively identified as subunits 8 and 11) of the ATPase-ATP synthase. Pantothenate modification of these enzyme subunits, which are synthesized on extramitochondrial ribosomes, may contribute to their transport and assembly into mitochondria, or it may participate in the catalytic activity of the assembled enzymes.     

Rhodamine 6G inhibits the matrix-catalyzed processing of precursors of rat-liver mitochondrial proteins

Several inner membrane proteins from rat liver mitochondria have been translated for the first time in rabbit reticulocyte lysates. These include the Rieske iron-sulfur protein, cytochrome c1 and core protein I of the cytochrome bc1 complex, the alpha and beta subunits of F1 ATPase, and subunit IV of cytochrome oxidase. All were translated from free polysomes as larger-molecular-mass precursors, and were processed to their mature forms by isolated liver mitochondria or by the isolated mitochondrial matrix fraction. In vitro processing, catalyzed by the isolated matrix fraction, is inhibited by rhodamine 6G. The latter is a fluorescent probe, which accumulates specifically in mitochondria of whole cells and which is used extensively to visualize mitochondrial morphology. The concentration of rhodamine 6G required for inhibition in vitro is similar to that of o-phenanthroline. Rhodamine 6G inhibits matrix-catalyzed processing of all precursors tested, indicating that the mechanism of inhibition is common for a variety of functionally unrelated precursors. The novel action of rhodamine 6G reported here can form the basis for its inhibition of precursor processing in intact hepatoma cells [Kolarov, J. & Nelson, B.D. (1984) Eur. J. Biochem. 144, 387-392].     

The functional and physical form of mammalian cytochrome c oxidase determined by gel filtration, radiation inactivation, and sedimentation equilibrium analysis

When solubilized in laurylmaltoside, cytochrome oxidases from beef heart and rat liver mitochondria exist as monodisperse populations that are stable, highly active, and have apparent molecular weights of 300,000 to 350,000, as measured by gel filtration. To determine whether these are monomeric (2 heme A, 2 Cu) or dimeric forms of the enzyme, we performed radiation inactivation and sedimentation equilibrium analyses. From radiation inactivation experiments under two different sets of conditions, we obtained estimates for the functional molecular weight of beef heart cytochrome oxidase of 114,000 and 99,000, much less than a dimer and significantly smaller than a 200,000 molecular weight monomer containing one copy of each of the 12 subunits normally present in the complex. The same functional size is obtained for a rat liver oxidase preparation depleted of subunit III. The physical molecular weight of cytochrome oxidase was determined by sedimentation equilibrium measurements in solvents of different densities using mixtures of H2O and D218O. Estimates of Mr = 194,000 +/- 9,000 for the beef heart oxidase and Mr = 152,000 +/- 6,000 for the rat liver enzyme were obtained, consistent with the size predicted for monomers of their subunit composition. From these results we conclude that mammalian cytochrome oxidases from beef heart and rat liver exist in laurylmaltoside as monomers capable of high rates of electron transfer and normal substrate binding. Further, these functions appear to be associated with a subset of the peptides present in the monomer, mainly composed of subunits I and II.     

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.     

Isolation, purification, and properties of boar sperm cytochrome oxidase

Cytochrome oxidase was isolated from the midpiece of boar sperm by extraction and fractionation with ammonium sulfate in the presence of cholate. The enzyme was further purified to apparent homogeneity by DEAE-cellulose column chromatography in the presence of minimal amounts of Triton X-100. The purified enzyme exhibited similar oxidized and reduced optical spectra to those of the bovine heart and rat liver cytochrome oxidases. However, the sperm oxidase was found to contain stoichiometrically more subunits I, II, and III than the other, smaller subunits. The sperm oxidase also required phospholipids for its activity, but it was less sensitive to inhibition by KCN. Interestingly, the sperm oxidase was much more acid-stable than the bovine heart and rat liver counterparts. The optimumpH for the sperm oxidase catalyzing the electron transfer between ferrocytochromec and cytochromea was aroundpH 4.8, and those for the bovine heart and rat liver were 6.2 and 6.8, respectively. AtpH 4.5, the sperm oxidase still maintained about 70% enzyme activity, whereas less than 20% activity remained in the heart and liver oxidases. The peculiar properties of sperm cytochrome oxidase may be due to the fact that the well-packed chromosomes in the sperm headpiece do not function, such that the nuclear gene-coded subunits are deficient in the sperm cytochrome oxidase. The finding that the sperm oxidase was more acid-stable is an example of structure-function coordination, and is discussed from the viewpoint of chemiosmotic theory and the unique structure and functions of the sperm mitochondria.     

Isolation, subunit composition, and site of synthesis of human cytochrome c oxidase

Cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1), the terminal oxidase of the respiratory chain in eucaryotic cells, has been purified from human placenta mitochondria. Seven polypeptides have been identified reproducibly by high-resolution electrophoresis of the enzyme complex through sodium dodecyl sulfate (Na-DodSO4)--urea polyacrylamide gels; these correspond closely in size to the subunits of beef heart cytochrome c oxidase. When HeLa cells, grown in suspension culture, were pulse-labeled with [35S]methionine in the presence of cycloheximide to inhibit cytoplasmic protein synthesis and chased with an excess of unlabeled methionine in the absence of the drug, the mitochondrially synthesized polypeptides were resolved into at least 17 components by NaDodSO4--urea polyacrylamide gel electrophoresis. After labeled HeLa mitochondria were mixed with human placenta mitochondria and the cytochrome c oxidase was isolated, three of the labeled components were found to copurify with the three largest subunits of the complex. We conclude that human cytochrome c oxidase contains seven subunits, the three largest of which are synthesized on mitochondrial ribosomes, while the other four are synthesized in the cytoplasm.     

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.     

Biosynthesis of rat liver transhydrogenase in vivo and in vitro

The biosynthesis of pyridine dinucleotide transhydrogenase, a homodimeric inner mitochondrial membrane redox-linked proton pump, has been studied in isolated rat hepatocytes. Newly synthesized transhydrogenase, having an apparent molecular weight identical to the enzyme of isolated liver mitochondria, was selectively immunoprecipitated from detergent extracts of isolated hepatocytes which were labeled with [35S]methionine. That the enzyme is a nuclear gene product is indicated since 1) synthesis was inhibited by cycloheximide, but not by chloramphenicol and 2) no synthesis could be demonstrated in hepatocyte ghosts which are competent only in mitochondrial translation. In addition to the mature form of the enzyme, a species about 2000 daltons larger was also immunoprecipitated from pulse-labeled cells. The half-life of the larger form during a subsequent chase at 37 degrees C was about 2 min, whereas the mature form was not degraded. The relationship between the two forms of the enzyme was established by in vitro studies. A protein approximately 2000 daltons larger than mature transhydrogenase was immunoisolated from a rabbit reticulocyte lysate system programmed with sucrose gradient fractionated rat liver mRNA. This protein was converted to a species having the same size as mature enzyme after incubation with either intact rat liver mitochondria or a soluble matrix fraction derived from mitoplasts. These studies indicate that transhydrogenase is synthesized in the cytoplasm as a higher molecular weight precursor which is post-translationally processed to the mature protein by a soluble matrix protease during or after membrane insertion.     

Immunochemical analysis of the membrane proteins of rat liver and Zajdela hepatoma mitochondria

The contents of mitochondrial inner membrane protein complexes were compared in normal liver and in Zajdela hepatoma mitochondria by the immunotransfer technique. Antibodies against core proteins 1 and 2, cytochrome c1, the iron-sulfur protein of Complex III, subunits I and II of cytochrome oxidase, and the alpha and beta subunits of the F1-ATPase were used. In addition, antibodies against a primary dehydrogenase, beta-hydroxybutyrate dehydrogenase, as well as the outer membrane pore protein were used. The results indicate that the components of the cytochrome chain and porin are greatly enriched in hepatoma mitochondria compared to normal rat liver mitochondria. This enrichment was also reflected in the rates of respiration in tumor mitochondria using a variety of substrates. Enrichment of porin may partially account for increased hexokinase binding to tumor mitochondria. In contrast to the respiratory chain components, the F1-ATPase and F0 (measured by DCCD binding) were not increased in tumor mitochondria. Thus, Zajdela hepatoma mitochondria components are nonstoichiometric, being enriched in oxidative capacity but relatively deficient in ATP synthesizing capacity. Finally, beta-hydroxybutyrate dehydrogenase, which is often decreased in hepatoma mitochondria, was shown here by immunological methods to be decreased by only 40%, whereas enzyme activity was less than 5% of that in normal rat liver.