Mass spectrometric analysis of the ubiquinol-binding site in cytochrome bd from Escherichia coli

Cytochrome bd is a heterodimeric terminal ubiquinol oxidase in the aerobic respiratory chain of Escherichia coli. For understanding the unique catalytic mechanism of the quinol oxidation, mass spectrometry was used to identify amino acid residue(s) that can be labeled with a reduced form of 2-azido-3-methoxy-5-methyl-6-geranyl-1,4-benzoquinone or 2-methoxy-3-azido-5-methyl-6-geranyl-1,4-benzoquinone. Matrix-assisted laser desorption ionization time-of-flight mass spectrometry demonstrated that the photo inactivation of ubiquinol-1 oxidase activity was accompanied by the labeling of subunit I with both azidoquinols. The cross-linked domain was identified by reverse-phase high performance liquid chromatography of subunit I peptides produced by in-gel double digestion with lysyl endopeptidase and endoproteinase Asp-N. Electrospray ionization quadrupole time-of-flight mass spectrometry determined the amino acid sequence of the peptide (m/z 1047.5) to be Glu(278)-Lys(283), where a photoproduct of azido-Q(2) was linked to the carboxylic side chain of I-Glu(280). This study demonstrated directly that the N-terminal region of periplasmic loop VI/VII (Q-loop) is a part of the quinol oxidation site and indicates that the 2- and 3-methoxy groups of the quinone ring are in the close vicinity of I-Glu(280).     

Identification of a Mr = 17,000 protein as the plastoquinone-binding protein in the cytochrome b6-f complex from spinach chloroplasts

An azidoquinone derivative, 3-azido-2-methyl-5-methoxy-6-(3,7-dimethyl[3H]octyl)-1,4-benzoquinone (azido-Q), was used to study the plastoquinone-protein interaction and to identify the plastoquinone-binding protein in the cytochrome b6-f complex from spinach chloroplasts. When the lipid- and plastoquinone-deficient cytochrome b6-f complex is incubated with varying concentrations of azido-Q and illuminated with long wavelength UV light for 7 min at 2 degrees C, the enzymatic activity, assayed after reconstitution with lipid, decreases as the concentration of azido-Q increases. Maximum inactivation (45%) is observed when 30 mol of azido-Q is used per mol of cytochrome f. The extent of the decrease in activity upon illumination correlates with the amount of azido-Q incorporated into the protein. The 50% inactivation is in good agreement with that expected based on the amount of plastoquinone deficiency of the isolated enzyme complex. When the photolyzed, [3H]azido-Q-treated sample is extracted with organic solvent and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis, radioactivity is found primarily in the Mr = 17,000 subunit. When the enzyme is pretreated with the electron transfer inhibitor 2,5-dibromo-3-methyl-6-isopropylbenzoquinone or 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole, significantly less radioactive label is observed in the Mr = 17,000 protein, suggesting that the action sites of these inhibitors are the same or near the plastoquinone-binding site. When the deficient complex is reconstituted with glycolipid prior to the addition of azido-Q, less than 5% inactivation is observed upon photolysis, and the amount of radioactive label on the Mr = 17,000 protein decreases greatly, suggesting that the plastoquinone-binding site is easily masked by glycolipid when endogenous plastoquinone is absent. Plastoquinol-2 apparently competes with azido-Q for the plastoquinone-binding site since it decreases the radioactive label on the Mr = 17,000 protein.     

Characterization of the cytochrome d terminal oxidase complex of Escherichia coli using polyclonal and monoclonal antibodies

The cytochrome d terminal oxidase complex is one of two terminal oxidases in the aerobic respiratory chain of Escherichia coli. Previous work has shown by dodecyl sulfate-polyacrylamide gel electrophoresis that this enzyme contains two subunits (I and II) and three cytochrome components, b558 , a1, and d. Reconstitution studies have demonstrated that the enzyme functions as a ubiquinol-8 oxidase and catalyzes an electrogenic reaction, i.e. turnover is accompanied by a charge separation across the membrane bilayer. In this paper, monoclonal and polyclonal antibodies were used to obtain structural information about the cytochrome d complex. It is shown that antibodies directed against subunit I effectively inhibit ubiquinol-1 oxidation by the purified enzyme in detergent, whereas antibodies which bind to subunit II have no effect on quinol oxidation. The oxidation rate of N,N,N',N'-tetramethyl-p-phenylenediamine, in contrast, is unaffected by antisubunit I antibodies, but is inhibited by antibodies against subunit II. It is concluded that the quinol oxidation site is on subunit I, previously shown to be the cytochrome b558 component of the complex, and that N,N,N',N'-tetramethyl-p-phenylenediamine oxidation occurs at a secondary site on subunit II. The antibodies were also used to analyze the results of a protein cross-linking experiment. Dimethyl suberimidate was used to cross-link the subunits of purified, solubilized oxidase. Immunoblot analysis of the products of this cross-linking clearly indicate that subunit II probably exists as a dimer within the complex. Finally, it is shown that the purified enzyme contains tightly bound lipopolysaccharide. This was revealed after discovering that one of the monoclonal antibodies raised against the purified complex is actually directed against lipopolysaccharide. The significance of this finding is not known.     

The cytochrome d complex is a coupling site in the aerobic respiratory chain of Escherichia coli

The cytochrome d complex from Escherichia coli has been reconstituted in proteoliposomes. Previous studies have shown that the enzyme rapidly oxidizes ubiquinol-8 within the bilayer as well as the soluble homologue, ubiquinol-1, and that quinol oxidase activity is accompanied by the formation of a transmembrane potential across the vesicle bilayer. In this work, the proton pumping activity of the cytochrome in the reconstituted vesicles is examined. Ubiquinol-1 oxidase activity is shown to be accompanied by the net alkalinization of the interior space of the reconstituted vesicles and by the release of protons in the external volume. H+/O ratios varying from 0.6 to 1.2 were measured in different preparations, by the oxygen pulse technique. Antibodies which bind specifically to subunit I (cytochrome b558) of the 2-subunit oxidase were used to estimate the topology of the reconstituted oxidase in the vesicles. It was concluded that 70-85% of the molecules were oriented with subunit I facing the outside and that this population of molecules is responsible for the observed proton release. Correction for the fraction of the oxidase which pumps protons into the vesicle interior yields an estimate of H+/O = 1.7 +/- 0.2. It is proposed that the enzyme does not function as an actual proton pump, but that the enzyme oxidizes ubiquinol and reduces oxygen (to water) on opposite faces of the membrane. Hence, scalar chemistry would yield H+/O = 2 and an electrogenic reaction by virtue of the transmembrane electron transfer between the proposed active sites.     

Modified, large-scale purification of the cytochrome o complex (bo-type oxidase) of Escherichia coli yields a two heme/one copper terminal oxidase with high specific activity.

The cytochrome o complex is a bo-type ubiquinol oxidase in the aerobic respiratory chain of Escherichia coli. This complex has a close structural and functional relationship with the eukaryotic and prokaryotic aa3-type cytochrome c oxidases. The specific activity, subunit composition, and metal content of the purified cytochrome o complex are not consistent for different preparative protocols reported in the literature. This paper presents a relatively simple preparation of the enzyme starting with a strain of Escherichia coli which overproduces the oxidase. The pure enzyme contains four subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Partial amino acid sequence data confirm the identities of subunit I, II, and III from the SDS-PAGE analysis as the cyoB, cyoA, and cyoC gene products, respectively. A slight modification of the purification protocol yields an oxidase preparation that contains a possible fifth subunit which may be the cyoE gene product. The pure four-subunit enzyme contains 2 equivs of iron but only 1 equiv of copper. There is no electron paramagnetic resonance detectable copper in the purified enzyme. Hence, the equivalent of CuA of the aa3-type cytochrome c oxidases is absent in this quinol oxidase. There is also no zinc in the purified quinol oxidase. Finally, monoclonal antibodies are reported that interact with subunit II. One of these monoclonals inhibits the quinol oxidase activity of the detergent-solubilized, purified oxidase. Hence, although subunit II does not contain CuA and does not interact with cytochrome c, it still must have an important function in the bo-type ubiquinol oxidase.     

Epitopes of monoclonal antibodies which inhibit ubiquinol oxidase activity of Escherichia coli cytochrome d complex localize functional domain.

The aerobic respiratory chain of Escherichia coli contains two terminal oxidases: the cytochrome d complex and the cytochrome o complex. Each of these enzymes catalyzes the oxidation of ubiquinol-8 within the cytoplasmic membrane and the reduction of molecular oxygen to water. Both oxidases are coupling sites in the respiratory chain; electron transfer from ubiquinol to oxygen results in the generation of a proton electrochemical potential difference across the membrane. The cytochrome d complex is a heterodimer (subunits I and II) that has three heme prosthetic groups. Previous studies characterized two monoclonal antibodies that bind to subunit I and specifically block the ability of the enzyme to oxidize ubiquinol. In this paper, the epitopes of both of these monoclonal antibodies have been mapped to within a single 11-amino acid stretch of subunit I. The epitope is located in a large hydrophilic loop between the fifth and sixth putative membrane-spanning segments. Binding experiments with these monoclonal antibodies show this polypeptide loop to be periplasmic. Such localization suggests that the loop may be close to His186, which has been identified as one of the axial ligands of cytochrome b558. Together, these data begin to define a functional domain in which ubiquinol is oxidized near the periplasmic surface of the membrane.     

Role of a bound ubiquinone on reactions of the Escherichia coli cytochrome bo with ubiquinol and dioxygen.

To probe the functional role of a bound ubiquinone-8 in cytochrome bo-type ubiquinol oxidase from Escherichia coli, we examined reactions with ubiquinol-1 and dioxygen. Stopped-flow studies showed that anaerobic reduction of the wild-type and the bound ubiquinone-free (DeltaUbiA) enzymes with ubiquinol-1 immediately takes place with four kinetic phases. Replacement of the bound ubiquinone with 2,6-dibromo-4-cyanophenol (PC32) suppressed the anaerobic reduction of the hemes with ubiquinol-1 by eliminating the fast phase. Flow-flash studies in the reaction of the fully reduced enzyme with dioxygen showed that the heme b-to-heme o electron transfer occurs with a rate constant of approximately 1x10(4) s(-1) in all three preparations. These results support our previous proposal that the bound ubiquinone is involved in facile oxidation of substrates in subunit II and subsequent intramolecular electron transfer to low-spin heme b in subunit I.     

Proteolysis of the cytochrome d complex with trypsin and chymotrypsin localizes a quinol oxidase domain.

The cytochrome d complex is a two-subunit, membrane-bound terminal oxidase in the aerobic respiratory chain of Escherichia coli. The enzyme catalyzes the two-electron oxidation of ubiquinol and the four-electron reduction of oxygen to water. Previous work demonstrated that the site for ubiquinol oxidation was selectively inactivated by limited proteolysis by trypsin, which cleaves at a locus within subunit I. This work is extended to show that a similar phenomenon is observed with limited chymotrypsin proteolysis of the complex. The cleavage patterns are similar whether one uses the purified oxidase in nondenaturing detergent or reconstituted in proteoliposomes or uses spheroplasts of E. coli as the substrate for the proteolysis. Hence, the protease-sensitive locus is periplasmic in the cell. Fragments resulting from proteolysis were characterized by N-terminal sequencing and by immunoblotting with the use of a monoclonal antibody of known epitope within subunit I. The data indicate that inactivation of the ubiquinol oxidase activity results from cleavage at specific residues with a hydrophilic region previously defined as the Q loop. This domain has been already implicated in ubiquinol oxidation by the use of inhibitory monoclonal antibodies. Electrochemical and HPLC analysis of the protease-cleaved oxidase suggests no global changes in either the quaternary or tertiary structure of the enzyme. It is likely that the Q loop is directly involved in forming a portion of the ubiquinol binding site near the periplasmic surface of the membrane.     

Specific labeling and partial inactivation of cytochrome oxidase by fluorescein mercuric acetate

Addition of 1 eq of fluorescein mercuric acetate (FMA) to beef heart cytochrome oxidase was found to inhibit the steady-state electron transfer activity by 50%, but further additions up to 10 eq had no additional effect on activity. The partial inhibition caused by FMA is thus similar to that observed with other mercury compounds (Mann, A. J., and Auer, H. E. (1980) J. Biol. Chem. 255, 454-458). The fluorescence of FMA was quenched by a factor of 10 upon binding to cytochrome oxidase, consistent with the involvement of a sulfhydryl group. However, addition of mercuric chloride to FMA-cytochrome oxidase resulted in an increase in fluorescence, suggesting that FMA was displaced from the high affinity binding site. Cytochrome c binding to FMA-cytochrome oxidase resulted in a 10% decrease in the fluorescence, possibly caused by Forster energy transfer from FMA to the cytochrome c heme. The binding site for FMA in cytochrome oxidase was investigated by carrying out sodium dodecyl sulfate gel electrophoresis under progressively milder dissociation conditions. When FMA-cytochrome oxidase was dissociated with 3% sodium dodecyl sulfate and 6 M urea, FMA was predominantly bound to subunit II following electrophoresis. However, when the dissociation was carried out at 4 degrees C in the absence of urea with progressively smaller amounts of lithium dodecyl sulfate, the labeling of subunit II decreased and that of subunit I increased. These experiments demonstrate that mercury compounds bind to a high affinity site on cytochrome oxidase, possibly located in subunit I, but then migrate to subunit II under the normal sodium dodecyl sulfate gel electrophoresis conditions. A definitive assignment of the high affinity binding site in the native enzyme cannot be made, however, because it is possible that mercury compounds can migrate from one sulfhydryl to another under even the mildest electrophoresis conditions.     

Specific overproduction and purification of the cytochrome b558 component of the cytochrome d complex from Escherichia coli

In Escherichia coli strain GR84N[pNG10], the cloned gene for subunit I of the membrane-bound cytochrome d complex resulted in the overproduction of cytochrome b558 and facilitated purification of this cytochrome. Extracting membranes with 1% Triton X-100 followed by two chromatographic steps yielded a single band on sodium dodecyl sulfate-polyacrylamide gels corresponding to subunit I (Mr 57 000). Purified cytochrome b558 was in its native state as determined by difference absorption spectroscopy and by potentiometric analysis. Both the membranes of strain GR84N[pNG10] and the purified subunit I lacked the other two spectroscopically defined cytochromes, b595 (previously "a1") and d, of the cytochrome d complex. Reconstitution of cytochrome b558 in phospholipid vesicles demonstrated that cytochrome b558 can be reduced by ubiquinol but that it does not reduce molecular oxygen. Heme extraction of cytochrome b558 yielded an extinction coefficient of 22 000 M-1 cm-1 for the wavelength pair of 560 and 580 nm in the reduced-minus-oxidized spectrum. The mutation on pNG10 that eliminates subunit II was mapped to a 250 base pair DNA fragment.     

Topological studies of monomeric and dimeric cytochrome c oxidase and identification of the copper A site using a fluorescence probe

Beef heart cytochrome c oxidase was labeled at a single sulfhydryl group by treatment with 5 mM N-iodoacetylamidoethyl-1-aminonaphthalene-5-sulfonate (1,5-I-AEDANS) at pH 8.0 for 4 h. Sodium dodecyl sulfate gel electrophoresis revealed that the enzyme was exclusively labeled at subunit III, presumably at Cys-115. The high affinity phase of the electron transfer reaction with horse cytochrome c was not affected by acetylamidoethyl-1-aminonaphthalene-5-sulfonate (AEDANS) labeling. Addition of horse cytochrome c to dimeric AEDANS-cytochrome c oxidase resulted in a 55% decrease in the AEDANS fluorescence due to the formation of a 1:1 complex between the two proteins. Forster energy transfer calculations indicated that the distance from the AEDANS label on subunit III to the heme group of cytochrome c was in the range 26-40 A. In contrast to the results with the dimeric enzyme, the fluorescence of monomeric AEDANS-cytochrome c oxidase was not quenched at all by binding horse heart cytochrome c, indicating that the AEDANS label on subunit III was at least 54 A from the heme group of cytochrome c. These results support a model in which the lysines surrounding the heme crevice of cytochrome c interact with carboxylates on subunit II of one monomer of the cytochrome c oxidase dimer and the back of the molecule is close to subunit III on the other monomer. In order to identify the cysteine residues that ligand copper A, a new procedure was developed to specifically remove copper A from cytochrome c oxidase by incubation with 2-mercaptoethanol followed by gel chromatography. Treatment of the copper A-depleted cytochrome c oxidase preparation with 1,5-I-AEDANS resulted in labeling sulfhydryl groups on subunit II as well as on subunit III. No additional subunits were labeled. This result indicates that the copper A binding site is located at cysteines 196 and/or 200 of subunit II and that removal of copper A exposes these residues for labeling by 1,5-I-AEDANS. Alternative copper A depletion methods involving incubation with bathocuproine sulfonate (Weintraub, S.T., and Wharton, D.C. (1981) J. Biol. Chem. 256, 1669-1676) or p-(hydroxymercuri)benzoate (Li, P.M., Gelles, J., Chan, S.I., Sullivan, R.J., and Scott, R.A. (1987) Biochemistry 26, 2091-2095) were also investigated. Treatment of these preparations with 1,5-I-AEDANS resulted in labeling cysteine residues on subunits II and III. However, additional sulfhydryl residues on other subunits were also labeled, preventing a definitive assignment of the location of copper A using these depletion procedures.     

Interaction and identification of ubiquinone-binding proteins in ubiquinol-cytochrome c reductase by azido-ubiquinone derivatives

Various azido-ubiquinone derivatives were synthesized and characterized. 3-Azido-2-methyl-5-methoxy-6-(3,7-dimethyloctyl)-1,4-benzoquinone was found to be suitable for the study of specific interaction between ubiquinone (Q) and protein. It was synthesized with high specific radioactivity and used to identify the Q-binding proteins in purified ubiquinol-cytochrome c reductase. This azido-Q derivative showed partial efficiency in restoring activity to the Q- and phospholipids-depleted ubiquinol-cytochrome c reductase in the absence of light. Azido-Q derivative treated samples, however, became completely inactivated upon photolysis, and the inactivation was not reversed by addition of Q derivatives. The redox state of the azido-Q derivative has little effect on the Q-binding affinity. Two protein subunits with Mr = 37,000 and 17,000 were found to be heavily labeled when depleted ubiquinol-cytochrome c reductase was treated with [3H] azido-Q derivative followed by photolysis and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The amount of radioactive labeling of the Mr = 17,000 protein was proportional to the degree of inactivation and affected by the presence of phospholipids. The radioactive labeling of the Mr = 37,000 protein subunit, however, showed no correlation with degree of inactivation and was not affected by phospholipids. Since the radiolabeling at the Mr = 17,000 protein subunit was affected by phospholipids and correlated with the enzymatic activity, this subunit is probably the Q-binding protein in this enzyme complex (QPc). The inhibition of enzymatic activity by n-heptyl-4-hydroxyquinoline-N-oxide was easily reversed by addition of the azido-Q derivative. The distribution of radioactivity among the subunits of ubiquinol-cytochrome c reductase was not affected by the presence of antimycin A, 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole or n-heptyl-4-hydroxyquinoline-N-oxide, suggesting that the binding site(s) of these inhibitors are not the Q-binding site.     

Expression of cyoA and cyoB demonstrates that the CO-binding heme component of the Escherichia coli cytochrome o complex is in subunit I

The cytochrome o complex of the Escherichia coli aerobic respiratory chain is a ubiquinol oxidase. The enzyme consists of at least four subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis and contains two heme b prosthetic groups (b555 and b562) plus copper. The sequence of the cyo operon, encoding the subunits of the oxidase, reveals five open reading frames, cyoABCDE. This paper describes results obtained by expressing independently cyoA and cyoB in the absence of the other subunits of the complex. Polyclonal antibodies which react with subunits I and II of the purified oxidase demonstrate that cyoA and cyoB correspond to subunit II and subunit I, respectively, of the complex. These subunits are stably inserted into the membrane when expressed. Furthermore, expression of cyoB (subunit I) results in elevated heme levels in the membrane. Reduced-minus-oxidized spectra suggest that the cytochrome b555 component is present but that the cytochrome b562 component is not. This heme component is shown to bind to CO, as it does in the intact enzyme. Hence, subunit I alone is sufficient for the assembly of the stable CO-binding heme component of this oxidase.     

Beta-galactosidase gene fusions as probes for the cytoplasmic regions of subunits I and II of the membrane-bound cytochrome d terminal oxidase from Escherichia coli

The cytochrome d terminal oxidase complex is a component of the aerobic respiratory chain of Escherichia coli. This enzyme catalyzes the oxidation of ubiquinol-8 within the cytoplasmic membrane and the reduction of molecular oxygen to water along with the concomitant generation of a proton-motive force across the membrane. Previous studies have established that the oxidase is composed of one copy of each of two subunits (I and II), and contains four heme prosthetic groups. The hydropathy profiles of the amino acid sequences suggest that each subunit has multiple transmembrane-spanning helical segments. The goal of the current work is to obtain experimental information about which portions of the two polypeptide chains are facing the cytoplasm. This is part of an effort to determine the topological folding of the two subunits across the membrane. A number of random gene fusions were generated in vitro which encode hybrid proteins in which the amino-terminal portion is provided by one of the two subunits of the oxidase, and the carboxyl-terminal portion is beta-galactosidase. Studies from other systems have indicated that the only hybrid proteins which will manifest high beta-galactosidase specific activity and be membrane-bound will be those where the fusion junction is in a region of the cytochrome polypeptides facing the cytoplasm. Fusions were obtained in eight positions within subunit I and 11 positions within subunit II. These identified four cytoplasmic-facing regions within subunit II, consistent with its hydropathy profile showing eight transmembrane helices. The data with subunit I are less conclusive.     

The sequence of the cyo operon indicates substantial structural similarities between the cytochrome o ubiquinol oxidase of Escherichia coli and the aa3-type family of cytochrome c oxidases

The cytochrome o complex is one of two ubiquinol oxidases in the aerobic respiratory system of Escherichia coli. This enzyme catalyzes the two-electron oxidation of ubiquinol-8 which is located in the cytoplasmic membrane, and the four-electron reduction of molecular oxygen to water. The purified oxidase contains at least four subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis and has been shown to couple electron flux to the generation of a proton motive force across the membrane. In this paper, the DNA sequence of the cyo operon, containing the structural genes for the oxidase, is reported. This operon is shown to encode five open reading frames, cyoABCDE. The gene products of three of these, cyoA, cyoB, and cyoC, are clearly related to subunits II, I, and III, respectively, of the eukaryotic and prokaryotic aa3-type cytochrome c oxidases. This family of cytochrome c oxidases contain heme a and copper as prosthetic groups, whereas the E. coli enzyme contains heme b (protoheme IX) and copper. The most striking sequence similarities relate the large subunits (I) of both the E. coli quinol oxidase and the cytochrome c oxidases. It is likely that the sequence similarities reflect a common molecular architecture of the two heme binding sites and of a copper binding site in these enzymes. In addition, the cyoE open reading frame is closely related to a gene denoted ORF1 from Paracoccus dentrificans which is located in between the genes encoding subunits II and III of the cytochrome c oxidase of this organism. The function of the ORF1 gene product is not known. These sequence relationships define a superfamily of membrane-bound respiratory oxidases which share structural features but which have different functions. The E. coli cytochrome o complex oxidizes ubiquinol but has no ability to catalyze the oxidation of reduced cytochrome c. Nevertheless, it is clear that the E. coli oxidase and the aa3-type cytochrome c oxidases must have very similar structures, at least in the vicinity of the catalytic centers, and they are very likely to have similar mechanisms for bioenergetic coupling (proton pumping).     

Deletion of subunit 9 of the Saccharomyces cerevisiae cytochrome bc1 complex specifically impairs electron transfer at the ubiquinol oxidase site (center P) in the bc1 complex.

Deletion of QCR9, the nuclear gene encoding subunit 9 of the mitochondrial cytochrome bc1 complex in Saccharomyces cerevisiae, results in inactivation of the bc1 complex and inability of the yeast to grow on non-fermentable carbon sources. The loss of bc1 complex activity is due to loss of electron transfer activity at the ubiquinol oxidase site (center P) in the complex. Electron transfer at the ubiquinone reductase site (center N), is unaffected by the loss of subunit 9, but the extent of cytochrome b reduction is diminished. This is the first instance in which a supernumerary polypeptide, lacking a redox prosthetic group, has been shown to be required for an electron transfer reaction within the cytochrome bc1 complex.     

Cytochrome b558 monitors the steady state redox state of the ubiquinone pool in the aerobic respiratory chain of Escherichia coli

The aerobic respiratory chain of Escherichia coli contains two terminal oxidases, the cytochrome o complex and the cytochrome d complex. These both function as ubiquinol-8 oxidases and reduce molecular oxygen to water. Electron flux is funneled from a variety of dehydrogenases, such as succinate dehydrogenase, through ubiquinone-8, to either of the terminal oxidases. A strain was examined which lacks the intact cytochrome d complex, but which overproduces one of the two subunits of this complex, cytochrome b558. This cytochrome, in the absence of the other subunit of the oxidase complex, does not possess catalytic activity. It is shown that the extent of reduction of cytochrome b558 in the E. coli membrane monitors the extent of reduction of the quinone pool in the membrane. The activity of each purified oxidase was examined in phospholipid vesicles as a function of the amount of ubiquinone-8 incorporated in the bilayer. A ratio of ubiquinol-8:phospholipid as low as 1:200 is sufficient to saturate each oxidase. The maximal turnover of the oxidases in the reconstituted system is considerably faster than observed in E. coli membranes, demonstrating that the rate-limiting step in the E. coli respiratory chain is at the dehydrogenases which feed electrons into the system.     

THE ROLE OF THE QUINONE POOL IN THE CYCLIC ELECTRON-TRANSFER CHAIN OF RHODOPSEUDOMONAS SPHAEROIDES: A MODIFIED Q-CYCLE MECHANISM

(1) The role of the ubiquinone pool in the reactions of the cyclic electron-transfer chain has been investigated by observing the effects of reduction of the ubiquinone pool on the kinetics and extent of the cytochrome and electrochromic carotenoid absorbance changes following flash illumination. (2) In the presence of antimycin, flash-induced reduction of cytochrome b-561 is dependent on a coupled oxidation of ubiquinol. The ubiquinol oxidase site of the ubiquinol:cytochrome c(2) oxidoreductase catalyses a concerted reaction in which one electron is transferred to a high-potential chain containing cytochromes c(1) and c(2), the Rieske-type iron-sulfur center, and the reaction center primary donor, and a second electron is transferred to a low-potential chain containing cytochromes b-566 and b-561. (3) The rate of reduction of cytochrome b-561 in the presence of antimycin has been shown to reflect the rate of turnover of the ubiquinol oxidase site. This diagnostic feature has been used to measure the dependence of the kinetics of the site on the ubiquinol concentration. Over a limited range of concentration (0-3 mol ubiquinol/mol cytochrome b-561), the kinetics showed a second-order process, first order with respect to ubiquinol from the pool. At higher ubiquinol concentrations, other processes became rate determining, so that above approx. 25 mol ubiquinol/mol cytochrome b-561, no further increase in rate was seen. (4) The kinetics and extents of cytochrome b-561 reduction following a flash in the presence of antimycin, and of the antimycin-sensitive reduction of cytochrome c(1) and c(2), and the slow phase of the carotenoid change, have been measured as a function of redox potential over a wide range. The initial rate for all these processes increased on reduction of the suspension over the range between 180 and 100 mV (pH 7). The increase in rate occurred as the concentration of ubiquinol in the pool increased on reduction, and could be accounted for in terms of the increased rate of ubiquinol oxidation. It is not necessary to postulate the presence of a tightly bound quinone at this site with altered redox properties, as has been previously assumed. (5) The antimycin-sensitive reactions reflect the turnover of a second catalytic site of the complex, at which cytochrome b-561 is oxidized in an electrogenic reaction. We propose that ubiquinone is reduced at this site with a mechanism similar to that of the two-electron gate of the reaction center. We suggest that antimycin binds at this site, and displaces the quinone species so that all reactions at the site are inhibited. (6) In coupled chromatophores, the turnover of the ubiquinone reductase site can be measured by the antimycin-sensitive slow phase of the electrochromic carotenoid change. At redox potentials higher than 180 mV, where the pool is completely oxidized, the maximal extent of the slow phase is half that at 140 mV, where the pool contains approx. 1 mol ubiquinone/mol cytochrome b-561 before the flash. At both potentials, cytochrome b-561 became completely reduced following one flash in the presence of antimycin. The results are interpreted as showing that at potentials higher than 180 mV, ubiquinol stoichiometric with cytochrome b-561 reaches the complex from the reaction center. The increased extent of the carotenoid change, when one extra ubiquinol is available in the pool, is interpreted as showing that the ubiquinol oxidase site turns over twice, and the ubiquinone reductase sites turns over once, for a complete turnover of the ubiquinol:cytochrome c(2) oxidoreductase complex, and the net oxidation of one ubiquinol/complex. (7) The antimycin-sensitive reduction of cytochrome c(1) and c(2) is shown to reflect the second turnover of the ubiquinol oxidase site. (8) We suggest that, in the presence of antimycin, the ubiquinol oxidase site reaches a quasi equilibrium with ubiquinol from the pool and the high- and low-potential chains, and that the equilibrium constant of the reaction catalysed constrains the site to the single turnover under most conditions. (9) The results are discussed in the context of a detailed mechanism. The modified Q-cycle proposed is described by physicochemical parameters which account well for the results reported.     

The structure of the ubiquinol oxidase from Escherichia coli and its ubiquinone binding site

Cell respiration is catalyzed by the heme-copper oxidase superfamily of enzymes, which comprises cytochrome c and ubiquinol oxidases. These membrane proteins utilize different electron donors through dissimilar access mechanisms. We report here the first structure of a ubiquinol oxidase, cytochrome bo3, from Escherichia coli. The overall structure of the enzyme is similar to those of cytochrome c oxidases; however, the membrane-spanning region of subunit I contains a cluster of polar residues exposed to the interior of the lipid bilayer that is not present in the cytochrome c oxidase. Mutagenesis studies on these residues strongly suggest that this region forms a quinone binding site. A sequence comparison of this region with known quinone binding sites in other membrane proteins shows remarkable similarities. In light of these findings we suggest specific roles for these polar residues in electron and proton transfer in ubiquinol oxidase.     

The catalytic role of subunit IV of the cytochrome b6-f complex from spinach chloroplast

The catalytic role of subunit IV, the Mr 17,000 protein, in the chloroplast cytochrome b6-f complex was established through trypsinolysis of the complex under controlled conditions. When purified chloroplast cytochrome b6-f complex, 1 mg/ml, in 50 mM Tris-succinate buffer (pH 7.0) containing 1% sodium cholate and 10% glycerol is treated with 80 micrograms of trypsin at room temperature for various lengths of time, the activity of the cytochrome b6-f complex decreases as the incubation time increases. A maximal inactivation of 80% is reached at 7 min of incubation. The trypsin inactivation is accompanied by the destruction of the proton translocation activity of the complex. No alteration of absorption and EPR spectral properties was observed in the trypsin-inactivated complex. Subunit IV is the only subunit in the cytochrome b6-f complex that is digested by trypsin, and the degree of digestion correlates with the decrease of electron transfer activity. The binding of azido-Q to subunit IV of the complex decreases as the extent of inactivation of the cytochrome b6-f complex by trypsin increases. The residue molecular mass of trypsin cleaved subunit IV is about 14 kDa, suggesting that the cleavage site is at lysine 119 or arginine 125 or 126. When the thylakoid membrane was assayed for cytochrome b6-f complex activity, very little activity was observed; and the activity was not sensitive to trypsinolysis. Upon sonication, activity and sensitivity to trypsinolysis was greatly increased, suggesting that subunit IV protrudes from the lumen side of the membrane.