Low-resolution structural studies of mitochondrial ubiquinol:cytochrome c reductase in detergent solutions by neutron scattering

Mitochondrial ubiquinol:cytochrome c reductase (Mr approximately 600,000) was cleaved into a complex (Mr approximately 280,000) of the subunits III (cytochrome b), IV (cytochrome c1) and VI to IX, a complex (Mr approximately 300,000) of the subunits I and II, and the single subunit V (iron-sulphur subunit, Mr approximately 25,000). Neutron scattering was applied to the whole enzyme, the cytochrome bc1 complex, both in hydrogenated and deuterated alkyl (phenyl) polyoxyethylene detergents, and the complex of subunits I and II in detergent-free solution. The neutron parameters were compared with the structures of the enzyme and the cytochrome bc1 complex previously determined by electron microscopy. Using the method of hard spheres, comparison of the calculated and experimental radius of gyration implies that the length of the enzyme across the bilayer or the detergent micelle is between 150 and 175 A and of the cytochrome bc1 complex between 90 and 115 A. The subunit topography was confirmed. The cleavage plane between the cytochrome bc1 complex and the complex of subunits I and II lies at the centre of the enzyme and runs parallel to the membrane just outside the bilayer. The detergent uniformly surrounds the protein as a belt, which is displaced by 30 to 40 A from the protein centre of the enzyme and by about 20 A from the protein centre of the cytochrome bc1 complex. The low protein matchpoint of the whole enzyme as compared to the subunit complexes is accounted for in terms of the non-exchange of about 30 to 60% of the exchangeable protons within the intact enzyme. Polar residues are, on average, at the protein surface and non-polar residues and polar residues with non-exchanged protons are buried within the enzyme.     

Role of PCDH10 and its hypermethylation in human gastric cancer

Cytochrome bc(1) complex catalyzes the reaction of electron transfer from ubiquinol to cytochrome c (or cytochrome c(2)) and couples this reaction to proton translocation across the membrane. Crystallization of the Rhodobacter sphaeroides bc(1) complex resulted in crystals containing only three core subunits. To mitigate the problem of subunit IV being dissociated from the three-subunit core complex during crystallization, we recently engineered an R. sphaeroides mutant in which the N-terminus of subunit IV was fused to the C-terminus of cytochrome c(1) with a 14-glycine linker between the two fusing subunits, and a 6-histidine tag at the C-terminus of subunit IV (c(1)-14Gly-IV-6His). The purified fusion mutant complex shows higher electron transfer activity, more structural stability, and less superoxide generation as compared to the wild-type enzyme. Preliminary crystallization attempts with this mutant complex yielded crystals containing four subunits and diffracting X-rays to 5.5? resolution.     

Purification of a cytochrome bc-aa3 supercomplex with quinol oxidase activity from Corynebacterium glutamicum. Identification of a fourth subunity of cytochrome aa3 oxidase and mutational analysis of diheme cytochrome c1

The aerobic respiratory chain of the Gram-positive Corynebacterium glutamicum involves a bc(1) complex with a diheme cytochrome c(1) and a cytochrome aa(3) oxidase but no additional c-type cytochromes. Here we show that the two enzymes form a supercomplex, because affinity chromatography of either strep-tagged cytochrome b (QcrB) or strep-tagged subunit I (CtaD) of cytochrome aa(3) always resulted in the copurification of the subunits of the bc(1) complex (QcrA, QcrB, QcrC) and the aa(3) complex (CtaD, CtaC, CtaE). The isolated bc(1)-aa(3) supercomplexes had quinol oxidase activity, indicating functional electron transfer between cytochrome c(1) and the Cu(A) center of cytochrome aa(3). Besides the known bc(1) and aa(3) subunits, few additional proteins were copurified, one of which (CtaF) was identified as a fourth subunit of cytochrome aa(3). If either of the two CXXCH motifs for covalent heme attachment in cytochrome c(1) was changed to SXXSH, the resulting mutants showed severe growth defects, had no detectable c-type cytochrome, and their cytochrome b level was strongly reduced. This indicates that the attachment of both heme groups to apo-cytochrome c(1) is not only required for the activity but also for the assembly and/or stability of the bc(1) complex.     

Large-scale purification and characterization of a highly active four-subunit cytochrome bc1 complex from Rhodobacter sphaeroides

A highly active, large-scale preparation of ubiquinol:cytochrome c2 oxidoreductase (EC 1.10.2.2; cytochrome bc1 complex) has been obtained from Rhodobacter sphaeroides. The enzyme was solubilized from chromatophores by using dodecyl maltoside in the presence of glycerol and was purified by anion-exchange and gel filtration chromatography. The procedure yields 35 mg of pure bc1 complex from 4.5 g of membrane protein, and its consistently results in an enzyme preparation that catalyzes the reduction of horse heart cytochrome c with a turnover of 250-350 (mumol of cyt c reduced).(mumol of cyt c1)-1.s-1. The turnover number is at least double that of the best preparation reported in the literature [Ljungdahl, P. O., Pennoyer, J. D., Robertson, D. C., & Trumpower, B. L. (1987) Biochim. Biophys. Acta 891, 227-241]. The scale is increased 25-fold, and the yield is markedly improved by using this protocol. Four polypeptide subunits were observed by SDS-PAGE, with Mr values of 40K, 34K, 24K, and 14K. N-Terminal amino acid sequences were obtained for cytochrome c1, the iron-sulfur protein subunit, and for cytochrome b and were identical with the expected protein sequences deduced from the DNA sequence of the fbc operon, with the exceptions that a 22-residue fragment is processed off of the N-terminus of cytochrome c1 and the N-terminal methionine residue is cleaved off both the b cytochrome and iron-sulfur protein subunits. Western blotting experiments indicate that subunit IV is not a contaminating light-harvesting complex polypeptide.(ABSTRACT TRUNCATED AT 250 WORDS)     

A four-subunit cytochrome bc(1) complex complements the respiratory chain of Thermus thermophilus

Several components of the respiratory chain of the eubacterium Thermus thermophilus have previously been characterized to various extent, while no conclusive evidence for a cytochrome bc(1) complex has been obtained. Here, we show that four consecutive genes encoding cytochrome bc(1) subunits are organized in an operon-like structure termed fbcCXFB. The four gene products are identified as genuine subunits of a cytochrome bc(1) complex isolated from membranes of T. thermophilus. While both the cytochrome b and the FeS subunit show typical features of canonical subunits of this respiratory complex, a further membrane-integral component (FbcX) of so far unknown function copurifies as a subunit of this complex. The cytochrome c(1) carries an extensive N-terminal hydrophilic domain, followed by a hydrophobic, presumably membrane-embedded helical region and a typical heme c binding domain. This latter sequence has been expressed in Escherichia coli, and in vitro shown to be a kinetically competent electron donor to cytochrome c(552), mediating electron transfer to the ba(3) oxidase. Identification of this cytochrome bc(1) complex bridges the gap between the previously reported NADH oxidation activities and terminal oxidases, thus, defining all components of a minimal, mitochondrial-type electron transfer chain in this evolutionary ancient thermophile.     

Purification of a three-subunit ubiquinol-cytochrome c oxidoreductase complex from Paracoccus denitrificans

A ubiquinol-cytochrome c oxidoreductase (cytochrome bc1) complex has been purified from the plasma membrane of aerobically grown Paracoccus denitrificans by extraction with dodecyl maltoside and ion exchange chromatography of the extract. The purified complex contains two spectrally and thermodynamically distinct b cytochromes, cytochrome c1, and a Rieske-type iron-sulfur protein. Optical spectra indicate absorption peaks at 553 nm for cytochrome c1 and at 560 and 566 nm for the high and low potential hemes of cytochrome b. The spectrum of cytochrome b560 is shifted to longer wavelength by antimycin. The Paracoccus bc1 complex consists of only three polypeptide subunits. On the basis of their relative electrophoretic mobilities, these have apparent molecular masses of 62, 39, and 20 kDa. The 62- and 39-kDa subunits have been identified as cytochromes c1 and b, respectively. The 20-kDa subunit is assumed to be the Rieske-type iron-sulfur protein on the basis of its molecular weight and the presence of an EPR-detectable signal typical of this iron-sulfur protein in the three-subunit complex. The Paracoccus bc1 complex catalyzes reduction of cytochrome c by ubiquinol with a turnover of 470 s-1. This activity is inhibited by antimycin, myxothiazol, stigmatellin, and hydroxyquinone analogues of ubiquinone, all of which inhibit electron transfer in the cytochrome bc1 complex of the mitochondrial respiratory chain. The electron transfer functions of the Paracoccus complex thus appear to be similar, and possibly identical, to those of the bc1 complex of eukaryotic mitochondria. The Paracoccus bc1 complex has the simplest subunit composition and one of the highest turnover numbers of any bc1 complex isolated from any species to date. These properties suggest that the structural requirements for electron transfer from ubiquinol to cytochrome c are met by a small number of peptides and that the "extra" peptides occurring in the mitochondrial bc1 complexes serve some other function(s), possibly in biogenesis or insertion of the complex into that organelle.     

Preparation and characterization of the water-soluble heme-binding domain of cytochrome c1 from the Rhodobacter sphaeroides bc1 complex.

The ubiquinol:cytochrome c2 oxidoreductase (bc1 complex) of Rhodobacter sphaeroides consists of four subunits. One of these subunits, cytochrome c1, is the site of interaction with cytochrome c2, a periplasmic protein. In addition, the sequences of the fbcC gene and of the cytochrome c1 subunit that it encodes suggest that the protein should be located on the periplasmic side of the cytoplasmic membrane and that it is anchored to the membrane by a single membrane-spanning alpha-helix located at the carboxyl-terminal end of the polypeptide. Site-directed mutagenesis of the fbcC gene was used to alter the codon for Gln228 to a stop codon. This results in the production of a truncated version of the cytochrome c1 subunit that lacks the membrane anchor at the carboxyl terminus. The bc1 complex fails to assemble properly as a result of this mutation, but the Rb. sphaeroides cells expressing the altered gene contain a water-soluble form of cytochrome c1 in the periplasm. The water-soluble cytochrome c1 was purified and characterized. The amino-terminal sequence is identical with that of the membrane-bound subunit, indicating the signal sequence is properly processed. High pressure liquid chromatography gel filtration chromatography indicates it is monomeric (28 kDa). The heme content and electrochemical properties are similar to those of the intact subunit within the complex. Flash-induced electron transfer kinetics measured using whole cells demonstrated that the water-soluble cytochrome c1 is competent as a reductant for cytochrome c2 within the periplasmic space. These data show that the isolated water-soluble cytochrome c1 retains many of the properties of the membrane-bound subunit of the bc1 complex and, therefore, will be useful for further structural and functional characterization.     

Biogenesis of mitochondrial ubiquinol:cytochrome c reductase (cytochrome bc1 complex). Precursor proteins and their transfer into mitochondria

The precursor proteins to the subunits of ubiquinol:cytochrome c reductase (cytochrome bc1 complex) of Neurospora crassa were synthesized in a reticulocyte lysate. These precursors were immunoprecipitated with antibodies prepared against the individual subunits and compared to the mature subunits immunoprecipitated or isolated from mitochondria. Most subunits were synthesized as precursors with larger apparent molecular weights (subunits I, 51,500 versus 50,000; subunit II, 47,500 versus 45,000; subunit IV (cytochrome c1), 38,000 versus 31,000; subunit V (Fe-S protein), 28,000 versus 25,000; subunit VII, 12,000 versus 11,500; subunit VIII, 11,600 versus 11,200). Subunit VI (14,000) was synthesized with the same apparent molecular weight. The post-translational transfer of subunits I, IV, V, and VII was studied in an in vitro system employing reticulocyte lysate and isolated mitochondria. The transfer and proteolytic processing of these precursors was found to be dependent on the mitochondrial membrane potential. In the transfer of cytochrome c1, the proteolytic processing appears to take place in two separate steps via an intermediate both in vivo and in vitro. In vivo, the intermediate form accumulated when cells were kept at 8 degrees C and was chased into mature cytochrome c1 at 25 degrees C. Both processing steps were energy-dependent.     

X-ray structure of the dimeric cytochrome bc(1) complex from the soil bacterium Paracoccus denitrificans at 2.7-Å resolution

The respiratory cytochrome bc(1) complex is a fundamental enzyme in biological energy conversion. It couples electron transfer from ubiquinol to cytochrome c with generation of proton motive force which fuels ATP synthesis. The complex from the α-proteobacterium Paracoccus denitrificans, a model for the medically relevant mitochondrial complexes, lacked structural characterization. We show by LILBID mass spectrometry that truncation of the organism-specific, acidic N-terminus of cytochrome c(1) changes the oligomerization state of the enzyme to a dimer. The fully functional complex was crystallized and the X-ray structure determined at 2.7-? resolution. It has high structural homology to mitochondrial complexes and to the Rhodobacter sphaeroides complex especially for subunits cytochrome b and ISP. Species-specific binding of the inhibitor stigmatellin is noteworthy. Interestingly, cytochrome c(1) shows structural differences to the mitochondrial and even between the two Rhodobacteraceae complexes. The structural diversity in the cytochrome c(1) surface facing the ISP domain indicates low structural constraints on that surface for formation of a productive electron transfer complex. A similar position of the acidic N-terminal domains of cytochrome c(1) and yeast subunit QCR6p is suggested in support of a similar function. A model of the electron transfer complex with membrane-anchored cytochrome c(552), the natural substrate, shows that it can adopt the same orientation as the soluble substrate in the yeast complex. The full structural integrity of the P. denitrificans variant underpins previous mechanistic studies on intermonomer electron transfer and paves the way for using this model system to address open questions of structure/function relationships and inhibitor binding.     

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.     

Affinity purification of cytochrome c reductase from potato mitochondria.

Ubiquinol-cytochrome-c oxidoreductase has been isolated from potato (Solanum tuberosum L.) mitochondria by cytochrome-c affinity chromatography and gel-filtration chromatography. The procedure, which up to now only proved applicable to Neurospora, yields a highly pure and active protein complex in monodisperse state. The molecular mass of the purified complex is about 650 kDa, indicating that potato cytochrome c reductase occurs as a dimer. Upon reconstitution into phospholipid membranes, the dimeric enzyme catalyzes electron transfer from a synthetic ubiquinol to equine cytochrome c with a turnover number of 50 s-1. The activity is inhibited by antimycin A and myxothiazol. A myxothiazol-insensitive and antimycin-sensitive transhydrogenation reaction, with a turnover number of 16 s-1, can be demonstrated as well. The protein complex consists of ten subunits, most of which have molecular masses similar to those of the nine-subunit fungal enzyme. Individual subunits were identified immunologically and spectral properties of b and c cytochromes were monitored. Interestingly, an additional 'core' polypeptide which is not present in other cytochrome bc1 complexes forms part of the enzyme from potato. Antibodies raised against individual polypeptides reveal that the core proteins are clearly immuno-distinguishable. The additional subunit may perform a specific function and contribute to the high molecular mass which exceeds those reported for other cytochrome-c-reductase dimers.     

Structural studies of cytochrome reductase. Subunit topography determined by electron microscopy of membrane crystals of a subcomplex

Ubiquinol: cytochrome c reductase was isolated from Neurospora mitochondria as a protein-detergent complex and dissociated by mild salt treatment. Three parts were obtained and characterized. Firstly, a complex containing the subunits III (cytochrome b), IV (cytochrome c1), VI, VII, VIII and IX; secondly, a complex containing the subunits I and II; and thirdly, the single subunit V (iron-sulphur subunit). Membrane crystals were prepared from the cytochrome bc1 subunit complex and by combining tilted electron microscopic views of the crystals, a low-resolution three-dimensional structure was calculated. This structure was compared to that of the whole cytochrome reductase (previously determined by electron microscopy of membrane crystals). Protein density absent from the structure of the subunit complex was then attributed to the missing subunits according to their size and shape and their association with the phospholipid bilayer.     

Biosynthesis of membrane-bound nitrate reductase in Escherichia coli: evidence for a soluble precursor.

Membrane-bound nitrate reductase of Escherichia coli consists of three subunits designated as A, B, and C, with subunit C being the apoprotein of cytochrome b, A hemA mutant that cannot synthesize delta-aminolevulinic acid (ALA) produces a normal, stable, membrane-bound enzyme when grown with ALA. When grown without ALA, this mutant makes a reduced amount of membrane-bound enzyme that is unstable and contains no C subunit. Under the same growth conditions, this mutant accumulates a large amount of a soluble form of the enzyme in the cytoplasm. Accumulation of this cytoplasmic form begins immediately upon induction of the enzyme with nitrate. The cytoplasmic form is very similar to the soluble form of the enzyme obtained by alkaline heat extraction. It is a high-molecular-weight complex with a Strokes radius of 8.0 nm and consists of intact A and B subunits. When ALA is added to a culture growing without ALA, the cytoplasmic form of the enzyme is incorporated into the membrane in a stable form, coincident with the formation of functional cytochrome b. Reconstitution experiments indicate that subunit C is present in cultures grown without ALA but is reduced in amount or unstable. These results indicate that membrane-bound nitrate reductase is synthesized via a soluble precursor containing subunits A and B, which then binds to the membrane upon interaction with the third subunit, cytochrome b.     

Identification and characterization of cytochrome bc(1) subcomplexes in mitochondria from yeast with single and double deletions of genes encoding cytochrome bc(1) subunits

We have examined the status of the cytochrome bc(1) complex in mitochondrial membranes from yeast mutants in which genes for one or more of the cytochrome bc(1) complex subunits were deleted. When membranes from wild-type yeast were resolved by native gel electrophoresis and analyzed by immunodecoration, the cytochrome bc(1) complex was detected as a mixed population of enzymes, consisting of cytochrome bc(1) dimers, and ternary complexes of cytochrome bc(1) dimers associated with one and two copies of the cytochrome c oxidase complex. When membranes from the deletion mutants were resolved and analyzed, the cytochrome bc(1) dimer was not associated with the cytochrome c oxidase complex in many of the mutant membranes, and membranes from some of the mutants contained a common set of cytochrome bc(1) subcomplexes. When these subcomplexes were fractionated by SDS/PAGE and analyzed with subunit-specific antibodies, it was possible to recognize a subcomplex consisting of cytochrome b, subunit 7 and subunit 8 that is apparently associated with cytochrome c oxidase early in the assembly process, prior to acquisition of the remaining cytochrome bc(1) subunits. It was also possible to identify a subcomplex consisting of subunit 9 and the Rieske protein, and two subcomplexes containing cytochrome c(1) associated with core protein 1 and core protein 2, respectively. The analysis of all the cytochrome bc(1) subcomplexes with monospecific antibodies directed against Bcs1p revealed that this chaperone protein is involved in a late stage of cytochrome bc(1) complex assembly.     

Biogenesis of the yeast cytochrome bc1 complex

The mitochondrial respiratory chain is composed of four different protein complexes that cooperate in electron transfer and proton pumping across the inner mitochondrial membrane. The cytochrome bc1 complex, or complex III, is a component of the mitochondrial respiratory chain. This review will focus on the biogenesis of the bc1 complex in the mitochondria of the yeast Saccharomyces cerevisiae. In wild type yeast mitochondrial membranes the major part of the cytochrome bc1 complex was found in association with one or two copies of the cytochrome c oxidase complex. The analysis of several yeast mutant strains in which single genes or pairs of genes encoding bc1 subunits had been deleted revealed the presence of a common set of bc1 sub-complexes. These sub-complexes are represented by the central core of the bc1 complex, consisting of cytochrome b bound to subunit 7 and subunit 8, by the two core proteins associated with each other, by the Rieske protein associated with subunit 9, and by those deriving from the unexpected interaction of each of the two core proteins with cytochrome c1. Furthermore, a higher molecular mass sub-complex is that composed of cytochrome b, cytochrome c1, core protein 1 and 2, subunit 6, subunit 7 and subunit 8. The identification and characterization of all these sub-complexes may help in defining the steps and the molecular events leading to bc1 assembly in yeast mitochondria.     

Further insights into the assembly of the yeast cytochrome bc1 complex based on analysis of single and double deletion mutants lacking supernumerary subunits and cytochrome b.

The cytochrome bc1 complex of the yeast Saccharomyces cerevisiae is composed of 10 different subunits that are assembled as a symmetrical dimer in the inner mitochondrial membrane. Three of the subunits contain redox centers and participate in catalysis, whereas little is known about the function of the seven supernumerary subunits. To gain further insight into the function of the supernumerary subunits in the assembly process, we have examined the subunit composition of mitochondrial membranes isolated from yeast mutants in which the genes for supernumerary subunits and cytochrome b were deleted and from yeast mutants containing double deletions of supernumerary subunits. Deletion of any one of the genes encoding cytochrome b, subunit 7 or subunit 8 caused the loss of the other two subunits. This is consistent with the crystal structure of the cytochrome bc1 complex that shows that these three subunits comprise its core, around which the remaining subunits are assembled. Absence of the cytochrome b/subunit 7/subunit 8 core led to the loss of subunit 6, whereas cytochrome c1, iron-sulfur protein, core protein 1, core protein 2 and subunit 9 were still assembled in the membrane, although in reduced amounts. Parallel changes in the amounts of core protein 1 and core protein 2 in the mitochondrial membranes of all of the deletion mutants suggest that these can be assembled as a subcomplex in the mitochondrial membrane, independent of the presence of any other subunits. Likewise, evidence of interactions between subunit 6, subunit 9 and cytochrome c1 suggests that a subcomplex between these two supernumerary subunits and the cytochrome might exist.     

An Engineered Cytochrome b6c1 Complex with a Split Cytochrome b Is Able To Support Photosynthetic Growth of Rhodobacter capsulatus

The ubihydroquinone-cytochrome c oxidoreductase (or the cytochrome bc1 complex) from Rhodobacter capsulatus is composed of the Fe-S protein, cytochrome b, and cytochrome c1 subunits encoded by petA(fbcF), petB(fbcB), and petC(fbcC) genes organized as an operon. In the work reported here, petB(fbcB) was split genetically into two cistrons, petB6 and petBIV, which encoded two polypeptides corresponding to the four amino-terminal and four carboxyl-terminal transmembrane helices of cytochrome b, respectively. These polypeptides resembled the cytochrome b6 and su IV subunits of chloroplast cytochrome b6f complexes, and together with the unmodified subunits of the cytochrome bc1 complex, they formed a novel enzyme, named cytochrome b6c1 complex. This membrane-bound multisubunit complex was functional, and despite its smaller amount, it was able to support the photosynthetic growth of R. capsulatus. Upon further mutagenesis, a mutant overproducing it, due to a C-to-T transition at the second base of the second codon of petBIV, was obtained. Biochemical analyses, including electron paramagnetic spectroscopy, with this mutant revealed that the properties of the cytochrome b6c1 complex were similar to those of the cytochrome bc1 complex. In particular, it was highly sensitive to inhibitors of the cytochrome bc1 complex, including antimycin A, and the redox properties of its b- and c-type heme prosthetic groups were unchanged. However, the optical absorption spectrum of its cytochrome bL heme was modified in a way reminiscent of that of a cytochrome b6f complex. Based on the work described here and that with Rhodobacter sphaeroides (R. Kuras, M. Guergova-Kuras, and A. R. Crofts, Biochemistry 37:16280-16288, 1998), it appears that neither the inhibitor resistance nor the redox potential differences observed between the bacterial (or mitochondrial) cytochrome bc1 complexes and the chloroplast cytochrome b6f complexes are direct consequences of splitting cytochrome b into two separate polypeptides. The overall findings also illustrate the possible evolutionary relationships among various cytochrome bc oxidoreductases.     

Phospholipase digestion of bound cardiolipin reversibly inactivates bovine cytochrome bc1.

Phospholipids and tightly bound cardiolipin (CL) can be removed from Tween 20 solubilized bovine cytochrome bc(1) (EC 1.10.2.2) by digestion with Crotalus atrox phospholipase A(2). The resulting CL-free enzyme exhibits all the spectral properties of native cytochrome bc(1), but is completely inactive. Full electron transfer activity is restored by exogenous cardiolipin added in the presence of dioleoylphosphatidylcholine (DOPC) and dioleoylphosphatidylethanolamine (DOPE), but not by cardiolipin alone or by mixtures of phospholipids lacking cardiolipin. Acidic, nonmitochondrial phospholipids, e.g., monolysocardiolipin or phosphatidylglycerol, partially reactivate CL-free cytochrome bc(1) if they are added together with DOPC and DOPE. Phospholipid removal from the Tween 20 solubilized enzyme, including the tightly bound cardiolipin, does not perturb the environment of either cytochrome b(562) or b(566), nor does it cause the autoreduction of cytochrome c(1). Cardiolipin-free cytochrome bc(1) also binds antimycin and myxothiazol normally with the expected red shifts in b(562) and b(566), respectively. However, the CL-free enzyme is much less stable than the lipid-rich preparation, i.e., (1) many chromatographic methods perturb both cytochrome b(566)() (manifested by a hypsochromic effect, i.e., blue shift of 1.5-1.7 nm) and cytochrome c(1) (evidenced by autoreduction in the absence of reducing agents); (2) affinity chromatographic purification of the enzyme causes pronounced loss of subunits VII and XI (65-80% decrease) and less significant loss of subunits I, IV, V, and X (20-30% decrease); and (3) high detergent-to-protein ratios result in disassembly of the complex. We conclude that the major role of the phospholipids surrounding cytochrome bc(1), especially cardiolipin, is to stabilize the quaternary structure. In addition, bound cardiolipin has an additional functional role in that it is essential for enzyme activity.     

Isolation and properties of cytochrome c oxidase from rat liver and quantification of immunological differences between isozymes from various rat tissues with subunit-specific antisera

Cytochrome c oxidase was isolated from rat liver either by affinity chromatography on cytochrome-c--Sepharose 4B or by chromatography on DEAE-Sepharose. Dodecyl sulfate gel electrophoresis of both preparations showed the same subunit pattern consisting of 13 different polypeptides. Kinetic analysis of the two preparations gave a higher Vmax for the enzyme isolated by chromatography on DEAE-Sephacel. Specific antisera were raised in rabbits against nine of the ten nuclear endoded subunits. A monospecific reaction of each antiserum with its corresponding subunit was obtained by Western blot analysis, thus excluding artificial bands in the gel electrophoretic pattern of the isolated enzyme due to proteolysis, aggregation or conformational modification of subunits. With an antiserum against rat liver holocytochrome c oxidase a different reactivity was found by Western blot analysis for subunits VIa and VIII between isolated cytochrome c oxidases from pig liver or kidney and heart or skeletal muscle. For a quantitative analysis of immunological differences a nitrocellulose enzyme-linked immunosorbent assay was developed. Monospecific antisera against 12 of the 13 subunits of rat liver cytochrome c oxidase were titrated with increasing amounts of total mitochondrial proteins from different rat tissues dissolved in dodecyl sulfate and dotted on nitrocellulose. The absorbance of a soluble dye developed by the second peroxidase-conjugated antibody was measured. From the data the following conclusions were obtained: (a) The mitochondrial encoded catalytic subunits I-III of cytochrome c oxidase are probably identical in all rat tissues. (b) All nine investigated nuclear encoded subunits of cytochrome c oxidase showed immunological differences between two or more tissues. Large immunological differences were found between liver, kidney or brain and heart or skeletal muscle. Minor but significant differences were observed for some subunits between heart and skeletal muscle and between liver, kidney and brain. (c) Between corresponding nuclear encoded subunits of cytochrome c oxidase from fetal and adult tissues of liver, heart and skeletal muscle apparent immunological differences were observed. The data could explain cases of fatal infantile myopathy due to cytochrome c oxidase deficiency.