Identification of subunit I as the cytochrome b558 component of the cytochrome d terminal oxidase complex of Escherichia coli

The cytochrome d terminal oxidase complex was recently purified from Escherichia coli membranes (Miller, M. J., and Gennis , R. B. (1983) J. Biol. Chem. 258, 9159-1965). The complex contains two polypeptides, subunits I and II, as shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and three spectroscopically defined cytochromes, b558 , a1, and d. A mutant that failed to oxidize N,N,N',N'-tetramethyl-p-phenylenediamine was obtained which was lacking this terminal oxidase complex and was shown to map at a locus called cyd on the E. coli genome. In this paper, localized mutagenesis was used to generate a series of mutants in the cytochrome d terminal oxidase. These mutants were isolated by a newly developed selection procedure based on their sensitivity to azide. Two classes of mutants which map to the cyd locus were obtained, cydA and cydB . The cydA phenotype included the lack of all three spectroscopically detectable cytochromes as well as the absence of both polypeptides, determined by immunological criteria. Strains manifesting the cydB phenotype lacked cytochromes a1 and d, but had a normal amount of cytochrome b558 . Immunological analysis showed that subunit I (57,000 daltons) was present in the membranes, but that subunit II (43,000 daltons) was missing. These data justify the conclusion that subunit I of this two-subunit complex can be identified as the cytochrome b558 component of the cytochrome d terminal oxidase complex.     

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.     

Location of heme axial ligands in the cytochrome d terminal oxidase complex of Escherichia coli determined by site-directed mutagenesis

The cytochrome d terminal oxidase complex is one of two terminal oxidases which are components of the aerobic respiratory chain of Escherichia coli. This membrane-bound enzyme catalyzes the two-electron oxidation of ubiquinol and the four-electron reduction of oxygen to water. Enzyme turnover generates proton and voltage gradients across the bilayer. The oxidase is a heterodimer containing 2 mol of protoheme IX and 1 or 2 mol of heme d per mol of complex. To explain the functional properties of the enzyme, a simple model has been proposed in which it is speculated that the heme prosthetic groups define two separate active sites on opposite sides of the membrane at which the oxidation of quinol and the reduction of water, respectively, are catalyzed. This paper represents an initial effort to define the axial ligands of each of the three or four hemes within the amino acid sequence of the oxidase subunits. Each of the 10 histidine residues has been altered by site-directed mutagenesis with the expectation that histidine residues are likely candidates for heme ligands. Eight of the 10 histidine residues are not essential for enzyme activity, and 2 appear to function as heme axial ligands. Histidine 186 in subunit I is required for the cytochrome b558 component of the enzyme. This residue is likely to be located near the periplasmic surface of the membrane. Histidine 19, near the amino terminus of subunit I also appears to be a heme ligand. It is concluded that two of the four or five expected heme axial ligands have been tentatively identified, although further work is required to confirm these conclusions. A minimum of two additional axial ligands must be residues other than histidine.     

Vitreoscilla hemoglobin binds to subunit I of cytochrome bo ubiquinol oxidases

The bacterium, Vitreoscilla, can induce the synthesis of a homodimeric hemoglobin under hypoxic conditions. Expression of VHb in heterologous bacteria often enhances growth and increases yields of recombinant proteins and production of antibiotics, especially under oxygen-limiting conditions. There is evidence that VHb interacts with bacterial respiratory membranes and cytochrome bo proteoliposomes. We have examined whether there are binding sites for VHb on the cytochrome, using the yeast two-hybrid system with VHb as the bait and testing every Vitreoscilla cytochrome bo subunit as well as the soluble domains of subunits I and II. A significant interaction was observed only between VHb and intact subunit I. We further examined whether there are binding sites for VHb on cytochrome bo from Escherichia coli and Pseudomonas aeruginosa, two organisms in which stimulatory effects of VHb have been observed. Again, in both cases a significant interaction was observed only between VHb and subunit I. Because subunit I contains the binuclear center where oxygen is reduced to water, these data support the function proposed for VHb of providing oxygen directly to the terminal oxidase; it may also explain its positive effects in Vitreoscilla as well as in heterologous organisms.     

Kinetics of intramolecular electron transfer in cytochrome bo3 from Escherichia coli

We have examined the temperature dependence of the intramolecular electron transfer (ET) between heme b and heme o(3) in CO-mixed valence cytochrome bo(3) (Cbo) from Escherichia coli. Upon photolysis of CO-mixed valence Cbo rapid ET occurs between heme o(3) and heme b with a rate constant of 2.2 x 10(5) s(-1) at room temperature. The corresponding rate of CO recombination is found to be 86 s(-1). From Eyring plots the activation energies for these two processes are found to be 3.4 kcal/mol and 6.7 kcal/mol for the ligand binding and ET reactions, respectively. Using variants of the Marcus equation the reorganization energy (lambda), electronic coupling factor (H(AB)), and the ET distance were found to be 1.4 +/- 0.2 eV, (2 +/- 1) x 10(-3) eV, and 9 +/- 1 A, respectively. These values are quite distinct from the analogous values previously obtained for bovine heart cytochrome c oxidase (CcO) (0.76 eV, 9.9 x 10(-5) eV, 13.2 A). The differences in mechanisms/pathways for heme b/heme o(3) and heme a/heme a(3) ET suggested by the Marcus parameters can be attributed to structural changes at the Cu(B) site upon change in oxidation state as well as differences in electronic coupling pathways between Heme b and heme o(3).     

Glutamate 107 in subunit I of the cytochrome bd quinol oxidase from Escherichia coli is protonated and near the heme d/heme b595 binuclear center

Cytochrome bd is a quinol oxidase from Escherichia coli, which is optimally expressed under microaerophilic growth conditions. The enzyme catalyzes the two-electron oxidation of either ubiquinol or menaquinol in the membrane and scavenges O2 at low concentrations, reducing it to water. Previous work has shown that, although cytochrome bd does not pump protons, turnover is coupled to the generation of a proton motive force. The generation of a proton electrochemical gradient results from the release of protons from the oxidation of quinol to the periplasm and the uptake of protons used to form H2O from the cytoplasm. Because the active site has been shown to be located near the periplasmic side of the membrane, a proton channel must facilitate the delivery of protons from the cytoplasm to the site of water formation. Two conserved glutamic acid residues, E107 and E99, are located in transmembrane helix III in subunit I and have been proposed to form part of this putative proton channel. In the current work, it is shown that mutations in either of these residues results in the loss of quinol oxidase activity and can result in the loss of the two hemes at the active site, hemes d and b595. One mutant, E107Q, while being totally inactive, retains the hemes. Fourier transform infrared (FTIR) redox difference spectroscopy has identified absorption bands from the COOH group of E107. The data show that E107 is protonated at pH 7.6 and that it is perturbed by the reduction of the heme d/heme b595 binuclear center at the active site. In contrast, mutation of an acidic residue known to be at or near the quinol-binding site (E257A) also inactivates the enzyme but has no substantial influence on the FTIR redox difference spectrum. Mutagenesis shows that there are several acidic residues, including E99 and E107 as well as D29 (in CydB), which are important for the assembly or stability of the heme d/heme b595 active site.     

Glutamate-89 in subunit II of cytochrome bo3 from Escherichia coli is required for the function of the heme-copper oxidase

Recent electrostatics calculations on the cytochrome c oxidase from Paracoccus denitrificans revealed an unexpected coupling between the redox state of the heme-copper center and the state of protonation of a glutamic acid (E78II) that is 25 A away in subunit II of the oxidase. Examination of more than 300 sequences of the homologous subunit in other heme-copper oxidases shows that this residue is virtually totally conserved and is in a cluster of very highly conserved residues at the "negative" end (bacterial cytoplasm or mitochondrial matrix) of the second transmembrane helix. The functional importance of several residues in this cluster (E89II, W93II, T94II, and P96II) was examined by site-directed mutagenesis of the corresponding region of the cytochrome bo(3) quinol oxidase from Escherichia coli (where E89II is the equivalent of residue E78II of the P. denitrificans oxidase). Substitution of E89II with either alanine or glutamine resulted in reducing the rate of turnover to about 43 or 10% of the wild-type value, respectively, whereas E89D has only about 60% of the activity of the control oxidase. The quinol oxidase activity of the W93V mutant is also reduced to about 30% of that of the wild-type oxidase. Spectroscopic studies with the purified E89A and E89Q mutants indicate no perturbation of the heme-copper center. The data suggest that E89II (E. coli numbering) is critical for the function of the heme copper oxidases. The proximity to K362 suggests that this glutamic acid residue may regulate proton entry or transit through the K-channel. This hypothesis is supported by the finding that the degree of oxidation of the low-spin heme b is greater in the steady state using hydrogen peroxide as an oxidant in place of dioxygen for the E89Q mutant. Thus, it appears that the inhibition resulting from the E89II mutation is due to a block in the reduction of the heme-copper binuclear center, expected for K-channel mutants.     

The quinone-binding sites of the cytochrome bo3 ubiquinol oxidase from Escherichia coli

Cytochrome bo₃ is the major respiratory oxidase located in the cytoplasmic membrane of Escherichia coli when grown under high oxygen tension. The enzyme catalyzes the 2-electron oxidation of ubiquinol-8 and the 4-electron reduction of dioxygen to water. When solubilized and isolated using dodecylmaltoside, the enzyme contains one equivalent of ubiquinone-8, bound at a high affinity site (Q_H). The quinone bound at the Q_H site can form a stable semiquinone, and the amino acid residues which hydrogen bond to the semiquinone have been identified. In the current work, it is shown that the tightly bound ubiquinone-8 at the Q_H site is not displaced by ubiquinol-1 even during enzyme turnover. Furthermore, the presence of high affinity inhibitors, HQNO and aurachin C1–10, does not displace ubiquinone-8 from the Q_H site. The data clearly support the existence of a second binding site for ubiquinone, the Q_L site, which can rapidly exchange with the substrate pool. HQNO is shown to bind to a single site on the enzyme and to prevent formation of the stable ubisemiquinone, though without displacing the bound quinone. Inhibition of the steady state kinetics of the enzyme indicates that aurachin C1–10 may compete for binding with quinol at the Q_L site while, at the same time, preventing formation of the ubisemiquinone at the Q_H site. It is suggested that the two quinone binding sites may be adjacent to each other or partially overlap.     

Assembly of the cytochrome bo3 complex

An understanding of the mechanisms that govern the assembly of macromolecular protein complexes is fundamental for studying their function and regulation. With this in mind, we have determined the assembly pathway for the membrane-embedded cytochrome bo(3) of Escherichia coli. We show that there is a preferred order of assembly, where subunits III and IV assemble first, followed by subunit I and finally subunit II. We also show that cofactor insertion catalyses assembly. These findings provide novel insights into the biogenesis of this model membrane protein complex.     

Projection structure of the cytochrome bo ubiquinol oxidase from Escherichia coli at 6 A resolution.

The haem-copper cytochrome oxidases are terminal catalysts of the respiratory chains in aerobic organisms. These integral membrane protein complexes catalyse the reduction of molecular oxygen to water and utilize the free energy of this reaction to generate a transmembrane proton gradient. Quinol oxidase complexes such as the Escherichia coli cytochrome bo belong to this superfamily. To elucidate the similarities as well as differences between ubiquinol and cytochrome c oxidases, we have analysed two-dimensional crystals of cytochrome bo by cryo-electron microscopy. The crystals diffract beyond 5 A. A projection map was calculated to a resolution of 6 A. All four subunits can be identified and single alpha-helices are resolved within the density for the protein complex. The comparison with the three-dimensional structure of cytochrome c oxidase shows the clear structural similarity within the common functional core surrounding the metal-binding sites in subunit I. It also indicates subtle differences which are due to the distinct subunit composition. This study can be extended to a three-dimensional structure analysis of the quinol oxidase complex by electron image processing of tilted crystals.     

Photothermal studies of CO photodissociation from mixed valence Escherichia coli cytochrome bo3

Here, we report the volume and enthalpy changes accompanying CO photodissociation from the mixed valence form of cytochrome bo3 oxidase from Escherichia coli. The results of photoacoustic calorimetry indicate two kinetic phases with distinct volume and enthalpy changes accompanying CO photodissociation from heme o3 and its transfer to CuB. The first phase occurring on a timescale of <50 ns is characterized by a volume decrease of -1.3+/-0.3 mL mol-1 and enthalpy change of 32+/-1.6 kcal mol-1. Subsequently, a volume increase of 2.9 mL mol-1 with an enthalpy change of -5.3+/-2.5 kcal mol-1 is observed with the lifetime of approximately 250 ns (this phase has not been detected in previous optical studies). These volume and enthalpy changes differ from the volume and enthalpy changes observed for CO dissociation from fully reduced cytochrome bo3 oxidase indicating that the heme o3/CuB active site dynamics are affected by the redox state of heme b.     

Mutagenesis of subunit N of the Escherichia coli complex I. Identification of the initiation codon and the sensitivity of mutants to decylubiquinone

The last gene in the nuo operon of Escherichia coli, nuoN, encodes a membrane-bound subunit of Complex I (NADH:ubiquinone oxidoreductase). In this report, the gene for subunit N was disrupted by a 163 bp deletion in the chromosome, resulting in the loss of Complex I function, as measured by deamino-NADH oxidase activity. This activity could be recovered after transformation of the mutant strain by a plasmid that contains the previously identified nuoN gene and the upstream intergenic region between nuoM and nuoN. Mutagenesis of the first ATG downstream of nuoM led to a loss of function, indicating that this is the likely initiation codon for nuoN, and predicting a protein of 485 amino acids and 52 044 Da. Thirty site-specific mutations in nuoN at 19 different positions were constructed in a vector that expresses the full-length subunit N with both an octahistidine tag and an HA epitope tag at the carboxyl terminus. Highly conserved charged and aromatic residues were selected for mutagenesis, as well as a substitution that occurs as a secondary mutation in Leber's hereditary optic neuropathy (LHON). Membranes from the mutant strains were tested for production of subunit N by immunoblots and for NADH-linked activities. Mutants with substitutions at six different positions (K158, K217, H224, K247, Y300, and K395) had rates of deamino-NADH oxidase activity that were no more than 50% of that of the wild type and had reduced rates of proton translocation. These mutants also showed enhanced inhibition by decylubiquinone, indicating that subunit N interacts with quinones. The mutation associated with LHON, G391S, had little effect on these functions.     

Transient formation of ubisemiquinone radical and subsequent electron transfer process in the Escherichia coli cytochrome bo

To elucidate a unique mechanism for the quinol oxidation in the Escherichia coli cytochrome bo, we applied pulse radiolysis technique to the wild-type enzyme with or without a single bound ubiquinone-8 at the high-affinity quinone binding site (Q(H)), using N-methylnicotinamide (NMA) as an electron mediator. With the ubiquinone bound enzyme, the reduction of the oxidase occurred in two phases as judged from kinetic difference spectra. In the faster phase, the transient species with an absorption maximum at 440 nm, a characteristic of the formation of ubisemiquinone anion radical, appeared within 10 micros after pulse radiolysis. In the slower phase, a decrease of absorption at 440 nm was accompanied by an increase of absorption at 428 and 561 nm, characteristic of the reduced form. In contrast, with the bound ubiquinone-8-free wild-type enzyme, NMA radicals directly reduced hemes b and o, though the reduction yield was low. These results indicate that a pathway for an intramolecular electron transfer from ubisemiquinone anion radical at the Q(H) site to heme b exists in cytochrome bo. The first-order rate constant of this process was calculated to be 1.5 x 10(3) s(-1) and is comparable to a turnover rate for ubiquinol-1. The rate constant for the intramolecular electron transfer decreased considerably with increasing pH, though the yields of the formation of ubisemiquinone anion radical and the subsequent reduction of the hemes were not affected. The pH profile was tightly linked to the stability of the bound ubisemiquinone in cytochrome bo [Ingledew, W. J., Ohnishi, T., and Salerno, J. C. (1995) Eur. J. Biochem. 227, 903-908], indicating that electron transfer from the bound ubisemiquinone at the Q(H) site to the hemes slows down at the alkaline pH where the bound ubisemiquinone can be stabilized. These findings are consistent with our previous proposal that the bound ubiquinone at the Q(H) site mediates electron transfer from the low-affinity quinol oxidation site in subunit II to low-spin heme b in subunit I.     

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.     

Location of heme a on subunits I and II and copper on subunit II of cytochrome c oxidase

A systemic study has been made of copper and heme a binding to subunits of beef heart cytochrome c oxidase. Copper and heme a were readily mobilized by ionic detergents, high ionic strengths, temperatures above 0 degrees C, thiol compounds, and gel-bound peroxides and free radicals when the subunits of the oxidase were dissociated from one another during polyacrylamide gel electrophoresis. Most subunits showed some affinity for heme a and copper under these conditions. However, in the presence of specific mixtures of ionic and nonionic detergents (e.g. 0.1% sodium dodecyl sulfate, 0.025% Triton X-100) at temperatures below 0 degrees C and in buffers of low ionic strength using 10 to 12% polyacrylamide gels preelectrophoresed for 3 days with thioglycolate, about 90% of the Cu was found on subunit II (Mr = 24,100), and heme a was found in equal amounts of subunits I (Mr = 35,800) and II. The oxidized-reduced and reduced-CO absorption spectra of these subunits resembled those of cytochrome c oxidase. It appears probable that in the native enzyme, subunit I contains heme a and subunit II contains copper and heme a. A relationship of mammalian cytochrome c oxidase to the two-subunit microbial cytochrome oxidase systems appears to exist.     

Superoxidized states of Escherichia coli sulfite reductase heme protein subunit

The oxidized forms of resting and sulfite-complexed Escherichia coli sulfite reductase heme protein subunit react with near-stoichiometric amounts of porphyrexide to produce what is best characterized as a ferrisiroheme pi cation radical. Addition of either sodium ascorbate or NADPH completely regenerates the parent form. Implications of these findings with respect to mechanisms of metal-radical J coupling and catalysis are discussed.     

Activated conformers of Escherichia coli sulfite reductase heme protein subunit

The heme protein subunit of Escherichia coli sulfite reductase shows enhanced reactivity with its substrate and a number of other ligands after a cycle of reduction and reoxidation at alkaline pH. At pH 9.5 this variant of the enzyme possesses at least four EPR-detectable, chloride-sensitive high-spin conformers, in contrast to the single chloride-insensitive species observed in the oxidized, resting enzyme at pH 7.7. Quantitative reversal of the spectral and ligand-binding properties of the "activated" enzyme to those of the resting enzyme is observed on reacidification to pH 7.7. At intermediate pH values, there occurs an acid-catalyzed relaxation of the activated enzyme to the resting form. This reaction is distinct from the one responsible for the accelerated ligand binding and production of multiple EPR conformers, which appears to be regulated by a process with a pK of 8.5.     

Identification of heme axial ligands of cytochrome c' from Alcaligenes sp. N.C.I.B. 11015

The spectral properties of both ferric and ferrous cytochromes c' from Alcaligenes sp. N.C.I.B. 11015 are reported. The EPR spectra at 77 K and the electronic, resonance Raman, CD and MCD spectra at room temperature have been compared with those of the other cytochromes c' and various hemoproteins. In the ferrous form, all the spectral results at physiological pH strongly indicated that the heme iron(II) is in a high-spin state. In the ferric form, the EPR and electronic absorption spectra were markedly dependent upon pH. EPR and electronic spectral results suggested that the ground state of heme iron(III) at physiological pH consists of a quantum mechanical admixture of an intermediate-spin and a high-spin state. Under highly alkaline conditions, identification of the axial ligands of heme iron(III) was attempted by crystal field analysis of the low-spin EPR g values. Upon the addition of sodium dodecyl sulfate to ferric and ferrous cytochrome c', the low-spin type spectra were induced. The heme environment of this low-spin species is also discussed.     

Activation volumes for intramolecular electron transfer in Escherichia coli cytochrome bo(3)

In this report we describe the activation volumes associated with the heme-heme electron transfer (ET) and CO rebinding to the binuclear center subsequent to photolysis of the CO-mixed-valence derivative of Escherichia coli cytochrome bo(3) (Cbo). The activation volumes associated with the heme-heme ET (k=1.2 x 10(5) s(-1)), and CO rebinding (k=57 s(-1)) are found to be +27.4 ml/mol and -2.6 ml/mol, respectively. The activation volume associated with the rebinding of CO is consistent with previous Cu X-ray absorption studies of Cbo where a structural change was observed at the Cu(B) site (loss of a histidine ligand) due to a change in the redox state of the binuclear center. In addition, the volume of activation for the heme-heme ET was found to be quite distinct from the activation volumes obtained for heme-heme ET in bovine heart Cytochrome c oxidase. Differences in mechanisms/pathways for heme b/heme o(3) and heme a/heme a(3) ET are suggested based on the associated activation volumes and previously obtained Marcus parameters.     

Role of Asp544 in subunit I for Na(+) pumping by Vitreoscilla cytochrome bo

The conserved Glu540 in subunit I of Escherichia coli cytochrome bo (a H(+) pump) is replaced by Asp544 in the Vitreoscilla enzyme (a Na(+) pump). Site-directed mutagenesis of the Vitreoscilla cytochrome bo operon changed this Asp to Glu, and both wild type and mutant cyo's were transformed into E. coli strain GV100, which lacks cytochrome bo. Compared to the wild type transformant the Asp544Glu transformant had decreased ability to pump Na(+) as well as decreased stimulation in respiratory activity in the presence of Na(+). Preliminary experiments indicated that this mutant also had increased ability to pump protons, suggesting that this single change may provide cation pumping specificity in this group of enzymes.