Change of the terminal oxidase from cytochrome a1 in shaking cultures to cytochrome o in static cultures of Acetobacter aceti.

Acetobacter aceti has an ability to grow under two different culture conditions, on shaking submerged cultures and on static pellicle-forming cultures. The respiratory chains of A. aceti grown on shaking and static cultures were compared, especially with respect to the terminal oxidase. Little difference was detected in several oxidase activities and in cytochrome b and c contents between the respiratory chains of both types of cells. Furthermore, the results obtained here suggested that the respiratory chains consist of primary dehydrogenases, ubiquinone, and terminal ubiquinol oxidase, regardless of the culture conditions. There was a remarkable difference, however, in the terminal oxidase, which is cytochrome a1 in cells in shaking culture but cytochrome o in cells grown statically. Change of the culture condition from shaking to static caused a change in the terminal oxidase from cytochrome a1 to cytochrome o, which is concomitant with an increase of pellicle on the surface of the static culture. In contrast, reappearance of cytochrome a1 in A. aceti was attained only after serial successive shaking cultures of an original static culture; cytochrome a1 predominated after the culture was repeated five times. In the culture of A. aceti, two different types of cells were observed; one forms a rough-surfaced colony, and the other forms a smooth-surfaced colony. Cells of the former type predominated in the static culture, while the cells of the latter type predominated in the shaking culture. Thus, data suggest that a change of the culture conditions, from static to shaking or vice versa, results in a change of the cell type, which may be related to the change in the terminal oxidase from cytochrome a1 to cytochrome o in A. aceti.     

Extended heme promiscuity in the cyanobacterial cytochrome c oxidase: characterization of native complexes containing hemes A, O, and D, respectively.

The cyanobacteria Anacystis nidulans (Synechococcus sp. PCC6301), Synechocystis sp. PCC6803, Anabaena sp. PCC 7120, and Nostoc sp. PCC8009 were grown photoautotrophically under reduced oxygen tension in a medium with sulfate replaced by thiosulfate and nitrate replaced by ammonium as the S- and N-sources, respectively. In addition, Anabaena and Nostoc were grown under dinitrogen-fixing conditions in a medium free of combined nitrogen. Membranes were isolated from late-logarithmic cells (culture density corresponding to approximately 3 microliters packed cells per milliliter); cytoplasmic and thylakoid membranes were separated and purified according to established procedures. Acid-labile hemes were extracted from the membranes and subjected to reversed-phase high-performance liquid chromatography. Separated hemes were analyzed spectroscopically and identified by comparison with authentic standards. In addition to hemes B, A, and O, the latter of which was induced under semianaerobic conditions only, substitution of thiosulfate and ammonium for the oxy-anions sulfate and nitrate led to the appearance of spectrally discernible heme D in the membranes and extracts therefrom. However, spectroscopic and kinetic investigation of the membrane-bound heme D rather disproved any reaction with oxygen or carbon monoxide. Kinetic measurements performed with the membrane-bound respiratory oxidase gave evidence for only two kinetically competent terminal oxidases, a3 and o3, both apparently associated with a single type of apoprotein, viz. subunit I of the known cyanobacterial aa3-type cytochrome c oxidase. The heme D, on the other hand, seems to form a spectrally distinguished, yet kinetically ill-defined hemoprotein complex which does not qualify as a fully functional d-type terminal oxidase on our (wild-type) cyanobacteria even after growth under semianaerobic pseudo-reducing conditions. Also growth (of Anabaena and Nostoc) under dinitrogen-fixing conditions did not change this situation. Thus, we are left with (wild-type) cyanobacteria forming an unbranched respiratory chain with only a single type of terminal oxidase protein, viz. the known aa3-type cytochrome c oxidase. This oxidase, however, may incorporate different prosthetic (heme) groups in the sense of "heme promiscuity." Biosynthesis of the different heme groups thereby seems to respond to the ambient redox environment. In particular, however, conditions for expression of the two quinol oxidases potentially and additionally coded for by the genome of, e. g., Synechocystis sp. PCC6803 (see http://www.kazusa.or.jp/cyano), have not yet been found.     

Recent studies of the cytochrome o terminal oxidase complex of Escherichia coli

The cytochrome o complex is the predominant terminal oxidase in the aerobic respiratory chain of Escherichia coli when the bacteria are grown under conditions of high aeration. The oxidase is a ubiquinol oxidase and reduces molecular oxygen to water. Electron transport through the enzyme is coupled to the generation of a protonmotive force. The purified cytochrome o complex contains four or five subunits, two protoheme IX (heme b) prosthetic groups, plus at least one Cu. The subunits are all encoded by the cyo operon. Sequence comparisons show that the cytochrome o complex is closely related to the aa3-type cytochrome c oxidase family. Gene fusions have been used to define the topology of each of the gene products. Subunits I, II, III and IV are proposed to have 15, 2, 5 and 3 transmembrane spans, respectively. The fifth gene product (cyoE) encodes a protein with 7 membrane spanning segments, and this may also be a subunit of this enzyme. Fourier transform infrared spectroscopy has been used to monitor CO bound in the active site where oxygen is reduced. These data provide definitive proof that the cytochrome o complex has a heme-copper binuclear center, similar to that present in the aa3-type cytochrome c oxidases. Site-directed mutagenesis is being utilized to define which amino acids are ligands to the heme iron and copper prosthetic groups.     

Molecular and spectroscopic analysis of the cytochrome cbb(3) oxidase from Pseudomonas stutzeri

Cytochrome cbb(3) oxidase, a member of the heme-copper oxidase superfamily, is characterized by its high affinity for oxygen while retaining the ability to pump protons. These attributes are central to its proposed role in the microaerobic metabolism of proteobacteria. We have completed the first detailed spectroscopic characterization of a cytochrome cbb(3) oxidase, the enzyme purified from Pseudomonas stutzeri. A combination of UV-visible and magnetic CD spectroscopies clearly identified four low-spin hemes and the high-spin heme of the active site. This heme complement is in good agreement with our analysis of the primary sequence of the ccoNOPQ operon and biochemical analysis of the complex. Near-IR magnetic CD spectroscopy revealed the unexpected presence of a low-spin bishistidine-coordinated c-type heme in the complex. This was shown to be one of two c-type hemes in the CcoP subunit by separately expressing the subunit in Escherichia coli. Separate expression of CcoP also allowed us to unambiguously assign each of the signals associated with low-spin ferric hemes present in the X-band EPR spectrum of the oxidized enzyme. This work both underpins future mechanistic studies on this distinctive class of bacterial oxidases and raises questions concerning the role of CcoP in electron delivery to the catalytic subunit.     

Determination of the ligands of the low spin heme of the cytochrome o ubiquinol oxidase complex using site-directed mutagenesis.

The cytochrome o complex of Escherichia coli is a ubiquinol oxidase which is the predominant respiratory terminal oxidase when the bacteria are grown under high oxygen tension. The amino acid sequences of three of the subunits of this quinol oxidase reveal a substantial relationship to the aa3-type cytochrome c oxidases. The two cytochrome components (b563.5 and o) and the single copper (CuB) present in the E. coli quinol oxidase appear to be equivalent to cytochrome a, cytochrome a3, and CuB of the aa3-type cytochrome c oxidases, respectively. These three prosthetic groups are all located within subunit I of the oxidase. Sequence alignments indicate only six totally conserved histidine residues among all known sequences of subunit I of the cytochrome c oxidases of various species plus the E. coli quinol oxidase. Site-directed mutagenesis has been used to change each of these totally conserved histidines with the presumption that two of these six must ligate to the low spin cytochrome center of the E. coli oxidase. The presence of the low spin cytochrome b563.5 component of the oxidase can be evaluated both by visible absorbance properties and by its EPR spectrum. The results unambiguously indicate that His-106 and His-421 are the ligands of the six-coordinate low spin cytochrome b563.5. Although the data are not definitive in making additional metal ligation assignments of the remaining four totally conserved histidines, a reasonable model is suggested for the structure of the catalytic core of the cytochrome o complex and, by extrapolation, of cytochrome c oxidase.     

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).     

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.     

Stopped-flow and rapid-scan studies of the redox behavior of cytochrome aco from facultative alkalophilic Bacillus

Cytochrome aco purified from an alkalophilic bacterium grown at pH 10 contains hemes a, b, and c as prosthetic groups, and their redox behavior was examined by using stopped-flow and rapid-scan techniques. Under anaerobic conditions the reduction of both heme a and c moieties with dithionite proceeded exponentially but with different rates, usually the former being reduced about 4 times faster than the latter. The reduction of protoheme was much slower, and a time-difference spectrum for this species was of a high spin type with absorption peaks at 433, 557, and 609 nm. Only the protoheme combined with CO, fulfilling the criteria for cytochrome o. Potentiometric titrations determined a midpoint potential of c heme to be 95 mV at pH 7.0 and 25 degrees C and suggested the presence of two forms of a heme with midpoint potentials of 250 and 323 mV. Cytochrome aco utilizes ascorbate plus N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) to reduce oxygen relatively rapidly without added cytochrome c (Qureshi, M. H., Yumoto, I., Fujiwara, T., Fukumori, Y., Yamanaka, T. (1990) J. Biochem. 107, 480-485). During the steady state, however, heme a stayed almost fully reduced in contrast to a partial reduction of heme c. Even after exhaustion of the dissolved oxygen the extent of reduction of heme c was 60-70% that attained by the dithionite reduction. When ascorbate plus TMPD-reduced cytochrome aco was exposed to oxygen the reduced heme c was oxidized rapidly whereas the oxidation of reduced a heme was negligibly slow. The full reduction of heme a during the steady state and its extremely slow oxidation rendered participation of heme a in the oxidase reaction less likely. A novel peak appearing transiently around 567 nm during the reaction was tentatively ascribed to an intermediate form of protoheme, or o heme, which was thus supposed to react directly with molecular oxygen. These results suggest strongly that the main electron transfer pathway would be c----o----oxygen. A possible role of a in regulating the electron flow through the main pathway and its functional relationship to a heme in the aa3-type cytochrome oxidase were discussed.     

Identification of heme and copper ligands in subunit I of the cytochrome bo complex in Escherichia coli.

The cytochrome bo complex is a terminal ubiquinol oxidase in the aerobic respiratory chain of Escherichia coli (Kita, K., Konishi, K., and Anraku, Y. (1984) J. Biol. Chem. 259, 3368-3374) and functions as a proton pump. It belongs to the heme-copper oxidase superfamily with the aa3-type cytochrome c oxidases in mitochondria and aerobic bacteria. In order to identify ligands of hemes and copper, we have substituted eight conserved histidines in subunit I by alanine and, in addition, His-106, -284, and -421 by glutamine and methionine. Western immunoblotting analysis showed that all the mutations do not affect the expression level of subunit I in the cytoplasmic membrane, indicating that these histidines are not crucial for its stability. A single copy expression vector carrying a single mutation at the invariant histidines, His-106, His-284, His-333, His-334, His-419, and His-421, of subunit I was unable to support the aerobic growth of a strain in which the chromosomal terminal oxidase genes (the cyo and cyd operons) have been deleted. The same mutations caused a complete loss of ubiquinol oxidase activity of the partially purified enzymes. Spectroscopic analysis of mutant oxidases in the cytoplasmic membrane revealed that substitutions of His-106 and -421 specifically eliminated a 563.5 nm peak of the low spin heme and that replacements of His-106, -284, and -419 reduced the extent of the CO-binding high spin heme. These spectroscopic properties of mutant oxidases were further confirmed with partially purified preparations. Atomic absorption analysis showed that substitutions of His-106, -333, -334, and -419 eliminated CuB almost completely. Based on these findings, we conclude that His-106 and -421 function as the axial ligands of the low spin heme and His-284 is a possible ligand of the high spin heme. His-333, -334, and -419 residues are attributed to the ligands of CuB. We present a helical wheel model of the redox center in subunit I, which consists of the membrane-spanning regions II, VI, VII, and X, and discuss the implications of the model.     

Evidence for multiple terminal oxidases, including cytochrome d, in facultatively alkaliphilic Bacillus firmus OF4.

The terminal oxidase content of Bacillus firmus OF4, a facultative alkaliphile that grows well over the pH range of 7.5 to 10.5, was studied by difference spectroscopy. Evidence was found for three terminal oxidases under different growth conditions. The growth pH and the stage of growth profoundly affected the expression of one of the oxidases, cytochrome d. The other two oxidases, cytochrome caa3 and cytochrome o, were expressed under all growth conditions tested, although the levels of both, especially cytochrome caa3, were higher at more alkaline pH (P.G. Quirk, A.A. Guffanti, R.J. Plass, S. Clejan, and T.A. Krulwich, Biochim. Biophys. Acta, in press). These latter oxidases were identified in everted membrane vesicles by reduced-versus-oxidized difference spectra (absorption maximum at 600 nm for cytochrome caa3) and CO-reduced-versus-reduced difference spectra (absorption maxima at 574 and 414 nm for cytochrome o). All three terminal oxidases were solubilized from everted membranes and partially purified. The difference spectra of the solubilized, partially purified cytochrome caa3 and cytochrome o complexes were consistent with these assignments. Cytochrome d, which has not been identified in a Bacillus species before, was tentatively assigned on the basis of its absorption maxima at 622 and 630 nm in reduced-versus-oxidized and CO-reduced-versus-reduced difference spectra, respectively, resembling the maxima exhibited by the complex found in Escherichia coli. The B. firmus OF4 cytochrome d was reducible by NADH but not by ascorbate-N,N,N',N'-tetramethyl-p-phenylenediamine in everted membrane vesicles. Cytochrome d was expressed under two conditions: in cells growing exponentially at pH 7.5 (but not at pH 10.5) and in cells stationary phase at either pH 7.5 or 10.5. Protein immunoblots with antibodies against subunit I of the E. coli cytochrome d complex reacted only with membrane vesicles that contained spectrally identifiable cytochrome d. Additional evidence that this B. firmus OF4 cytochrome is related to the E. coli complex was obtained with a solubilized, partially purified fraction of cytochrome d that also reacted with antibodies against the subunits of the E. coli cytochrome d.     

Redox control of fast ligand dissociation from Escherichia coli cytochrome bd

Bacterial bd-type quinol oxidases, such as cytochrome bd from Escherichia coli, contain three hemes, but no copper. In contrast to heme-copper oxidases and similarly to globins, single electron-reduced cytochrome bd forms stable complexes with O(2), NO and CO at ferrous heme d. Kinetics of ligand dissociation from heme d(2+) in the single electron- and fully-reduced cytochrome bd from E. coli has been investigated by rapid mixing spectrophotometry at 20 degrees C. Data show that (i) O(2) dissociates at 78 s(-1), (ii) NO and CO dissociation is fast as compared to heme-copper oxidases and (iii) dissociation in the single electron-reduced state is hindered as compared to the fully-reduced enzyme. Presumably, rapid ligand dissociation requires reduced heme b(595). As NO, an inhibitor of respiratory oxidases, is involved in the immune response against microbial infection, the rapid dissociation of NO from cytochrome bd may have important bearings on the patho-physiology of enterobacteria.     

Identification of 27-oxo-octacosanoic acid and heptacosane-1,27-dioic acid in Legionella pneumophila

A strain of Escherichia coli having elevated levels of cytochrome bo and lacking the cytochrome bd quinol oxidase was grown in chemostat culture at low copper levels. Such cells had lowered levels of copper and of total cytochrome b. Cytochrome o concentration was unchanged when assayed by conventional CO difference spectroscopy, but apparently diminished by 80% in copper-deficient cells as determined by photodissociation of bound CO at 193 K. This is attributed to depletion of copper in the oxidase of copper-deficient cells, causing rapid recombination of photodissociated CO to haem O. CO recombination was also more sensitive to low intensities of actinic light in copper-depleted oxidase. The results illustrate a further similarity between the active sites of o- and aa3-type terminal oxidases.     

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.     

Human neutrophil cytochrome b contains multiple hemes. Evidence for heme associated with both subunits.

Human phagocyte cytochrome b is the terminal component of the microbicidal superoxide generating system. Although the primary structure of this protein has been determined, little is known about the placement of the heme prosthetic groups in this heterodimeric integral membrane protein. Analysis of the cytochrome using lithium dodecyl sulfate-polyacrylamide gel electrophoresis at 0 degree C followed by tetramethylbenzidine heme staining demonstrated the presence of heme in both the 91- and 22-kDa subunits identified by Western blot analysis using peptide specific antisera. Exposure of cytochrome b (purified or in isolated neutrophil plasma membranes) to Staphylococcal protease V8 or trypsin did not affect absorbance spectra. However, such treatment resulted in degradation of both subunits to smaller fragments, including characteristic immunoreactive 20-kDa fragments of both the large and small subunits of the cytochrome that retained one or both of the hemes. The spectral stability to proteolysis and size of the proteolytic heme-containing fragments generated explains previous reports which suggested that the heme resided in the small subunit. Our current results indicate that human neutrophil cytochrome b is a bi-heme or possibly tri-heme molecule with at least one heme residing in the large subunit and one shared between both subunits and that the heme-containing regions of the cytochrome probably lie within the membrane lipid bilayer. Such a multi-heme structure would be consistent with an electron transfer function for this cytochrome by providing an efficient mechanism for transferring electrons across the plasma membrane to the extracellular surface where oxygen could be reduced to create superoxide.     

A novel copper A containing menaquinol NO reductase from Bacillus azotoformans

The molecular biology and biochemistry of denitrification in gram-negative bacteria has been studied extensively. However, little is known about this process in gram-positive bacteria. We have purified the NO reductase from the cytoplasmic membrane of the gram-positive bacterium Bacillus azotoformans. The purified enzyme consists of two subunits with apparent molecular masses of 16 and 40 kDa based on SDS-PAGE. Analytical and spectroscopic determinations revealed the presence of one non-heme iron, two copper atoms and of two b-type hemes per enzyme complex. Heme c was absent. Using EPR and UV-visible spectroscopy, it was determined that one of the hemes is a low-spin heme b, in which the two axial histidine imidazole planes are positioned at an angle of 60-70 degrees. The second heme b is high-spin binding CO in the reduced state. The high-spin heme center and the non-heme iron are EPR silent. They are proposed to form a binuclear center where reduction of NO occurs. There are two novel features of this enzyme that distinguish it from other NO reductases. First, the enzyme contains copper in form of copper A, an electron carrier up to now only detected in cytochrome oxidases and nitrous oxide reductases. Second, the enzyme uses menaquinol as electron donor, whereas cytochrome c, which is the substrate of other NO reductases, is not used. Copper A and both hemes are reducible by menaquinol. This new NO reductase is thus a menaquinol:NO oxidoreductase. With respect to its prosthetic groups the B. azotoformans NO reductase is a true hybrid between copper A containing cytochrome oxidases and NO reductases present in gram-negative bacteria. It may represent the most ancient "omnipotent" progenitor of the family of heme-copper oxidases.     

Complex interactions of carbon monoxide with reduced cytochrome cbb3 oxidase from Pseudomonas stutzeri

Cytochrome cbb(3) oxidase, from Pseudomonas stutzeri, contains a total of five hemes, two of which, a b-type heme in the active site and a hexacoordinate c-type heme, can bind CO in the reduced state. By comparing the cbb(3) oxidase complex and the isolated CcoP subunit, which contains the ligand binding bishistidine-coordinated c-type heme, we have deconvoluted the contribution made by each center to CO binding. A combination of rapid mixing and flash photolysis experiments, coupled with computer simulations, reveals the kinetics of the reaction of c-type heme with CO to be complex as a result of the need to displace an endogenous axial ligand, a property shared with nonsymbiotic plant hemoglobins and some heme-based gas sensing domains. The recombination of CO with heme b(3), unlike all other heme-copper oxidases, including mitochondrial cytochrome c oxidase, is independent of ligand concentration. This observation suggests a very differently organized dinuclear center in which CO exchange between Cu(B) and heme b(3) is significantly enhanced, perhaps reflecting an important determinant of substrate affinity.     

Nitrobacter winogradskyi cytochrome a1c1 is an iron-sulfur molybdoenzyme having hemes a and c

Cytochrome a1c1 (nitrite-cytochrome c oxidoreductase) purified from Nitrobacter winogradskyi (formerly N. agilis) contained molybdenum, non-heme iron, and acid-labile sulfur in addition to hemes a and c; it contained 1 mol of heme a, 4-5 g atoms of non-heme iron, 2-5 g atoms of acid-labile sulfur, and 1-2 g atoms of molybdenum per mol of heme c, but did not contain copper. The fluorescence spectra of the molybdenum cofactor derivative prepared from cytochrome a1c1 were very similar to those of the cofactor derivative from xanthine oxidase, and the aponitrate reductase of nit-1 mutant of Neurospora crassa was complemented by addition of the molybdenum cofactor derived from the cytochrome. Further, the ESR spectrum of cytochrome a1c1 was similar to that of liver sulfite oxidase. The content of cytochrome a1 in the cells cultivated with the medium in which tungsten was substituted for molybdenum markedly decreased as compared with that in the cells cultivated in the molybdenum-supplemented medium. These results indicate that cytochrome a1c1 is an iron-sulfur molybdoenzyme which contains hemes a and c.     

Isolation and characterization of a new class of cytochrome d terminal oxidase mutants of Escherichia coli.

Cytochrome d terminal oxidase mutants were isolated by using hydroxylamine mutagenesis of pNG2, a pBR322-derived plasmid containing the wild-type cyd operon. The mutagenized plasmid was transformed into a cyo cyd recA strain, and the transformants were screened for the inability to confer aerobic growth on nonfermentable carbon sources. Western blot analysis and visible-light spectroscopy were performed to characterize three independent mutants grown both aerobically and anaerobically. The mutational variants of the cytochrome d complex were stabilized under anaerobic growth conditions. All three mutations perturb the b595 and d heme components of the complex. These mutations were mapped and sequenced and are shown to be located in the N-terminal third of subunit II of the cytochrome d complex. It is proposed that the N terminus of subunit II may interact with subunit I to form an interface that binds the b595 and d heme centers.     

Structure, function, and assembly of heme centers in mitochondrial respiratory complexes

The sequential flow of electrons in the respiratory chain, from a low reduction potential substrate to O(2), is mediated by protein-bound redox cofactors. In mitochondria, hemes-together with flavin, iron-sulfur, and copper cofactors-mediate this multi-electron transfer. Hemes, in three different forms, are used as a protein-bound prosthetic group in succinate dehydrogenase (complex II), in bc(1) complex (complex III) and in cytochrome c oxidase (complex IV). The exact function of heme b in complex II is still unclear, and lags behind in operational detail that is available for the hemes of complex III and IV. The two b hemes of complex III participate in the unique bifurcation of electron flow from the oxidation of ubiquinol, while heme c of the cytochrome c subunit, Cyt1, transfers these electrons to the peripheral cytochrome c. The unique heme a(3), with Cu(B), form a catalytic site in complex IV that binds and reduces molecular oxygen. In addition to providing catalytic and electron transfer operations, hemes also serve a critical role in the assembly of these respiratory complexes, which is just beginning to be understood. In the absence of heme, the assembly of complex II is impaired, especially in mammalian cells. In complex III, a covalent attachment of the heme to apo-Cyt1 is a prerequisite for the complete assembly of bc(1), whereas in complex IV, heme a is required for the proper folding of the Cox 1 subunit and subsequent assembly. In this review, we provide further details of the aforementioned processes with respect to the hemes of the mitochondrial respiratory complexes. This article is part of a Special Issue entitled: Cell Biology of Metals.     

Interaction of the bacterial terminal oxidase cytochrome bd with nitric oxide

Cytochrome bd is a prokaryotic terminal oxidase catalyzing O2 reduction to H2O. The oxygen-reducing site has been proposed to contain two hemes, d and b595, the latter presumably replacing functionally CuB of heme-copper oxidases. We show that NO, in competition with O2, rapidly and potently (Ki = 100 +/- 34 nM at approximately 70 microM O2) inhibits cytochrome bd isolated from Escherichia coli and Azotobacter vinelandii in turnover, inhibition being quickly and fully reverted upon NO depletion. Under anaerobic reducing conditions, neither of the two enzymes reveals NO reductase activity, which is proposed to be associated with CuB in heme-copper oxidases.