Dynamic water networks in cytochrome cbb3 oxidase

Heme-copper oxidases (HCOs) are terminal electron acceptors in aerobic respiration. They catalyze the reduction of molecular oxygen to water with concurrent pumping of protons across the mitochondrial and bacterial membranes. Protons required for oxygen reduction chemistry and pumping are transferred through proton uptake channels. Recently, the crystal structure of the first C-type member of the HCO superfamily was resolved [Buschmann et al. Science 329 (2010) 327–330], but crystallographic water molecules could not be identified. Here we have used molecular dynamics (MD) simulations, continuum electrostatic approaches, and quantum chemical cluster calculations to identify proton transfer pathways in cytochrome cbb₃. In MD simulations we observe formation of stable water chains that connect the highly conserved Glu323 residue on the proximal side of heme b₃ both with the N- and the P-sides of the membrane. We propose that such pathways could be utilized for redox-coupled proton pumping in the C-type oxidases. Electrostatics and quantum chemical calculations suggest an increased proton affinity of Glu323 upon reduction of high-spin heme b₃. Protonation of Glu323 provides a mechanism to tune the redox potential of heme b₃ with possible implications for proton pumping.     

Transmembrane proton translocation by cytochrome c oxidase

Respiratory heme-copper oxidases are integral membrane proteins that catalyze the reduction of molecular oxygen to water using electrons donated by either quinol (quinol oxidases) or cytochrome c (cytochrome c oxidases, CcOs). Even though the X-ray crystal structures of several heme-copper oxidases and results from functional studies have provided significant insights into the mechanisms of O₂-reduction and, electron and proton transfer, the design of the proton-pumping machinery is not known. Here, we summarize the current knowledge on the identity of the structural elements involved in proton transfer in CcO. Furthermore, we discuss the order and timing of electron-transfer reactions in CcO during O₂ reduction and how these reactions might be energetically coupled to proton pumping across the membrane.     

Active Site of Cytochrome cbb3

Cytochrome cbb₃ is the most distant member of the heme-copper oxidase family still retaining the following major feature typical of these enzymes: reduction of molecular oxygen to water coupled to proton translocation across the membrane. The thermodynamic properties of the six redox centers, five hemes and a copper ion, in cytochrome cbb₃ from Rhodobacter sphaeroides were studied using optical and EPR spectroscopy. The low spin heme b in the catalytic subunit was shown to have the highest midpoint redox potential (E_m,7 +418 mV), whereas the three hemes c in the two other subunits titrated with apparent midpoint redox potentials of +351, +320, and +234 mV. The active site high spin heme b₃ has a very low potential (E_m,7 -59 mV) as opposed to the copper center (Cu_B), which has a high potential (E_m,7 +330 mV). The EPR spectrum of the ferric heme b₃ has rhombic symmetry. To explain the origins of the rhombicity, the Glu-383 residue located on the proximal side of heme b₃ was mutated to aspartate and to glutamine. The latter mutation caused a 10 nm blue shift in the optical reduced minus oxidized heme b₃ spectrum, and a dramatic change of the EPR signal toward more axial symmetry, whereas mutation to aspartate had far less severe consequences. These results strongly suggest that Glu-383 is involved in hydrogen bonding to the proximal His-405 ligand of heme b₃, a unique interaction among heme-copper oxidases.The heme-copper oxidases form a family of enzymes that have structural homology of the catalytic subunit in common (1). This family of proteins, characterized by six conserved histidine ligands of the redox cofactors, ranges from classical, mitochondrial terminal oxidases to nitric-oxide reductases, and the members have been classified according to evolutionary relationships of their sequences (2–4). The bacterial cbb₃-type cytochrome c oxidases form a distinct, divergent subfamily within the heme-copper oxidases (5). Terminal oxidases share the catalytic activity of four-electron reduction of molecular oxygen to water coupled to translocation of protons across the membrane (6, 7). Cytochrome cbb₃, expressed in some bacteria as a sole terminal oxidase, is characterized by its ability to maintain catalytic activity under low oxygen tension (8), and it has also been shown to have the capacity to translocate protons (9).The Rhodobacter sphaeroides cytochrome cbb₃ is encoded by the ccoNOQP operon composed of four genes (10). The catalytic subunit CcoN homes a binuclear active site composed of a high spin heme b₃ and a nearby copper ion (Cu_B). There are altogether four low spin hemes in the enzyme. In addition to a protoheme (heme b) residing in the vicinity of the active site in subunit CcoN, there are three hemes c present in the soluble domains of the two other transmembrane subunits, a monoheme subunit CcoO and a diheme subunit CcoP (11). There is yet one more membrane-spanning subunit, CcoQ, without bound cofactors (12). Although the catalytic subunit shows homology to the other heme-copper oxidases (13), the other three subunits bear no resemblance to subunits of other types of terminal oxidases. However, subunit CcoO has been shown to have sequence homology with the nitric-oxide reductase subunit NorC (14).The crystal structures of a few heme-copper oxidases have been resolved (15–19), but only structural homology models are currently available for cytochromes cbb₃ (20–23). Apart from the signatures common to all heme-copper oxidases, the sequence alignments have revealed only very few other conserved residues when terminal oxidases are compared. Even though some amino acids, absent from cytochrome cbb₃, have been shown to be of critical importance to the function of the classical heme-copper oxidases, the major functions still remain the same in all of these enzymes.The thermodynamic properties of the cbb₃-type oxidases have been investigated sparsely. Apart from work yielding partial information about the properties of the hemes (11, 24, 25), two more complete studies have been carried out (5, 26). All the hemes in cytochrome cbb₃ were proposed to have high redox potentials, both in the Pseudomonas stutzeri and Bradyrhizobium japonicum enzymes (5, 26). This is also the case in all other studies, except for the enzyme from Rhodothermus marinus, where two low potential redox centers were reported (25). However, little is known about the copper center in the active site (Cu_B). Early Fourier transform infrared (FTIR)² spectroscopic measurements identified the presence of a heme/copper binuclear center in R. sphaeroides cytochrome cbb₃ (11), and more recent resonance Raman and FTIR studies have given additional information about the structure of the active site (27–29).In the absence of deconvoluted spectral components and thereby clear assignments of the redox centers in the cbb₃-type oxidases, and the lack of consensus about their thermodynamic properties, a complete study was required. In this work we have set out to investigate the thermodynamic properties of all the redox centers in cytochrome cbb₃ from R. sphaeroides using a combination of optical and EPR redox titrations with the main focus on the details of the catalytic site. This effort will form a basis for further mechanistic studies.     

Structural characterization of a binuclear center of a Cu-containing NO reductase homologue from Roseobacter denitrificans: EPR and resonance Raman studies

Aerobic phototrophic bacterium Roseobacter denitrificans has a nitric oxide reductase (NOR) homologue with cytochrome c oxidase (CcO) activity. It is composed of two subunits that are homologous with NorC and NorB, and contains heme c, heme b, and copper in a 1:2:1 stoichiometry. This enzyme has virtually no NOR activity. Electron paramagnetic resonance (EPR) spectra of the air-oxidized enzyme showed signals of two low-spin hemes at 15 K. The high-spin heme species having relatively low signal intensity indicated that major part of heme b₃ is EPR-silent due to an antiferromagnetic coupling to an adjacent Cu_B forming a Fe-Cu binuclear center. Resonance Raman (RR) spectrum of the oxidized enzyme suggested that heme b₃ is six-coordinate high-spin species and the other hemes are six-coordinate low-spin species. The RR spectrum of the reduced enzyme showed that all the ferrous hemes are six-coordinate low-spin species. ν(Fe-CO) and ν(C-O) stretching modes were observed at 523 and 1969 cm⁻¹, respectively, for CO-bound enzyme. In spite of the similarity to NOR in the primary structure, the frequency of ν(Fe-CO) mode is close to those of aa₃- and bo₃-type oxidases rather than that of NOR.     

Combined effect of loss of the caa3 oxidase and Crp regulation drives Shewanella to thrive in redox-stratified environments

Shewanella species are a group of facultative Gram-negative microorganisms with remarkable respiration abilities that allow the use of a diverse array of terminal electron acceptors (EA). Like most bacteria, S. oneidensis possesses multiple terminal oxidases, including two heme-copper oxidases (caa₃- and cbb₃-type) and a bd-type quinol oxidase. As aerobic respiration is energetically favored, mechanisms underlying the fact that these microorganisms thrive in redox-stratified environments remain vastly unexplored. In this work, we discovered that the cbb₃-type oxidase is the predominant system for respiration of oxygen (O₂), especially when O₂ is abundant. Under microaerobic conditions, the bd-type quinol oxidase has a significant role in addition to the cbb₃-type oxidase. In contrast, multiple lines of evidence suggest that under test conditions the caa₃-type oxidase, an analog to the mitochondrial enzyme, has no physiological significance, likely because of its extremely low expression. In addition, expression of both cbb₃- and bd-type oxidases is under direct control of Crp (cAMP receptor protein) but not the well-established redox regulator Fnr (fumarate nitrate regulator) of canonical systems typified in Escherichia coli. These data, collectively, suggest that adaptation of S. oneidensis to redox-stratified environments is likely due to functional loss of the caa₃-type oxidase and switch of the regulatory system for respiration.     

Redox-coupled proton pumping in cytochrome c oxidase: Further insights from computer simulation

The membrane-bound enzyme cytochrome c oxidase, the terminal member in the respiratory chain, converts oxygen into water and generates an electrochemical gradient by coupling the electron transfer to proton pumping across the membrane. Here we have investigated the dynamics of an excess proton and the surrounding protein environment near the active sites. The multi-state empirical valence bond (MS-EVB) molecular dynamics method was used to simulate the explicit dynamics of proton transfer through the critically important hydrophobic channel between Glu242 (bovine notation) and the D-propionate of heme a₃ (PRDa₃) for the first time. The results from these molecular dynamics simulations indicate that the PRDa₃ can indeed re-orientate and dissociate from Arg438, despite the high stability of such an ion pair, and has the ability to accept protons via bound water molecules. Any large conformational change of the adjacent heme a D-propionate group is, however, sterically blocked directly by the protein. Free energy calculations of the PRDa₃ side chain isomerization and the proton translocation between Glu242 and the PRDa₃ site have also been performed. The results exhibit a redox state-dependent dynamical behavior and indicate that reduction of the low-spin heme a may initiate internal transfer of the pumped proton from Glu242 to the PRDa₃ site.     

Electron transfer patterns of the di-heme protein cytochrome c4 from Pseudomonas stutzeri

We report kinetic data for the two-step electron transfer (ET) oxidation and reduction of the two-domain di-heme redox protein Pseudomonas stutzeri cytochrome (cyt) c₄ by [Co(bipy)₃]^2+/3+ (bipy = 2,2′-bipyridine). Following earlier reports, the data accord with both bi- and tri-exponential kinetics. A complete kinetic scheme includes both “cooperative” intermolecular ET between each heme group and the external reaction partner, and intramolecular ET between the two heme groups. A new data analysis scheme shows unequivocally that two-ET oxidation and reduction of P. stutzeri cyt c₄ is entirely dominated by intermolecular ET between the heme groups and the external reaction partner in the ms time range, with virtually no contribution from intramolecular interheme ET in this time range. This is in striking contrast to two-ET electrochemical oxidation or reduction of P. stutzeri cyt c₄ for which fast, ms to sub-ms intramolecular interheme ET is a crucial step. The rate constant dependence on the solvent viscosity has disclosed strong coupling to both a (set of) frictionally damped solvent/protein nuclear modes and intramolecular friction-less “ballistic” modes, indicative of notable protein structural mobility in the overall two-ET process. We suggest that conformational protein mobility blocks intramolecular interheme ET in bulk homogeneous solution but triggers opening of this gated ET channel in the electrochemical environment or in the membrane environment of natural respiratory cyt c₄ function.     

Electrostatic control of proton pumping in cytochrome c oxidase

As part of the mitochondrial respiratory chain, cytochrome c oxidase utilizes the energy produced by the reduction of O₂ to water to fuel vectorial proton transport. The mechanism coupling proton pumping to redox chemistry is unknown. Recent advances have provided evidence that each of the four observable transitions in the complex catalytic cycle consists of a similar sequence of events. However, the physico-chemical basis underlying this recurring sequence has not been identified. We identify this recurring pattern based on a comprehensive model of the catalytic cycle derived from the analysis of oxygen chemistry and available experimental evidence. The catalytic cycle involves the periodic repetition of a sequence of three states differing in the spatial distribution of charge in the active site: [0|1], [1|0], and [1|1], where the total charge of heme a and the binuclear center appears on the left and on the right, respectively. This sequence recurs four times per turnover despite differences in the redox chemistry. This model leads to a simple, robust, and reproducible sequence of electron and proton transfer steps and rationalizes the pumping mechanism in terms of electrostatic coupling of proton translocation to redox chemistry. Continuum electrostatic calculations support the proposed mechanism and suggest an electrostatic origin for the decoupled and inactive phenotypes of ionic mutants in the principal proton-uptake pathway.     

Substrate binding and the catalytic reactions in cbb3-type oxidases: The lipid membrane modulates ligand binding

Heme–copper oxidases (HCuOs) are the terminal components of the respiratory chain in the mitochondrial membrane or the cell membrane in many bacteria. These enzymes reduce oxygen to water and use the free energy from this reaction to maintain a proton-motive force across the membrane in which they are embedded. The heme–copper oxidases of the cbb₃-type are only found in bacteria, often pathogenic ones since they have a low K_m for O₂, enabling the bacteria to colonize semi-anoxic environments. Cbb₃-type (C) oxidases are highly divergent from the mitochondrial-like aa₃-type (A) oxidases, and within the heme–copper oxidase family, cbb₃ is the closest relative to the most divergent member, the bacterial nitric oxide reductase (NOR). Nitric oxide reductases reduce NO to N₂O without coupling the reaction to the generation of any electrochemical proton gradient. The significant structural differences between A- and C-type heme–copper oxidases are manifested in the lack in cbb₃ of most of the amino acids found to be important for proton pumping in the A-type, as well as in the different binding characteristics of ligands such as CO, O₂ and NO. Investigations of the reasons for these differences at a molecular level have provided insights into the mechanism of O₂ and NO reduction as well as the proton-pumping mechanism in all heme–copper oxidases. In this paper, we discuss results from these studies with the focus on the relationship between proton transfer and ligand binding and reduction. In addition, we present new data, which show that CO binding to one of the c-type hemes of CcoP is modulated by protein–lipid interactions in the membrane. These results show that the heme c-CO binding can be used as a probe of protein–membrane interactions in cbb₃ oxidases, and possible physiological consequences for this behavior are discussed.     

The Rieske/cytochrome b complex of Heliobacteria

Heliobacteria have a Rieske/cytochrome b complex composed of a Rieske protein, a cytochrome b_6, a subunit IV and a di-heme cytochrome c. The overall structure of the complex seems close to the b₆f complex from cyanobacteria and chloroplasts to the exception of the di-heme cytochrome. We show here by biochemical and biophysical studies that a heme c_i is covalently attached to the Rieske/cytochrome b complex from Heliobacteria. We studied the EPR signature of this heme in two different species, Heliobacterium modesticaldum and Heliobacillus mobilis. In contrast to the case of b₆f complex, a strong axial ligand to the heme is present, most probably a protonatable amino acid residue.     

Nitric oxide and peroxynitrite cause irreversible increases in the Km for oxygen of mitochondrial cytochrome oxidase: in vitro and in vivo studies

Mitochondrial cytochrome oxidase is competitively and reversibly inhibited by inhibitors that bind to ferrous heme, such as carbon monoxide and nitric oxide. In the case of nitric oxide, nanomolar levels inhibit cytochrome oxidase by competing with oxygen at the enzyme's heme-copper active site. This raises the K_m for cellular respiration into the physiological range. This effect is readily reversible and may be a physiological control mechanism. Here we show that a number of in vitro and in vivo conditions result in an irreversible increase in the oxygen K_m. These include: treatment of the purified enzyme with peroxynitrite or high (μM) levels of nitric oxide; treatment of the endothelial-derived cell line, b.End5, with NO; activation of astrocytes by cytokines; reperfusion injury in the gerbil brain. Studies of cell respiration that fail to vary the oxygen concentration systematically are therefore likely to significantly underestimate the degree of irreversible damage to cytochrome oxidase.     

A Biochemical Approach to Study the Role of the Terminal Oxidases in Aerobic Respiration in Shewanella oneidensis MR-1

The genome of the facultative anaerobic γ-proteobacterium Shewanella oneidensis MR-1 encodes for three terminal oxidases: a bd-type quinol oxidase and two heme-copper oxidases, a A-type cytochrome c oxidase and a cbb ₃-type oxidase. In this study, we used a biochemical approach and directly measured oxidase activities coupled to mass-spectrometry analysis to investigate the physiological role of the three terminal oxidases under aerobic and microaerobic conditions. Our data revealed that the cbb ₃-type oxidase is the major terminal oxidase under aerobic conditions while both cbb ₃-type and bd-type oxidases are involved in respiration at low-O₂ tensions. On the contrary, the low O₂-affinity A-type cytochrome c oxidase was not detected in our experimental conditions even under aerobic conditions and would therefore not be required for aerobic respiration in S. oneidensis MR-1. In addition, the deduced amino acid sequence suggests that the A-type cytochrome c oxidase is a ccaa ₃-type oxidase since an uncommon extra-C terminal domain contains two c-type heme binding motifs. The particularity of the aerobic respiratory pathway and the physiological implication of the presence of a ccaa ₃-type oxidase in S. oneidensis MR-1 are discussed.     

A decade of crystallization drops: Crystallization of the cbb3 cytochrome c oxidase from Pseudomonas stutzeri

The cbb₃ cytochrome c oxidases are distant members of the superfamily of heme copper oxidases. These terminal oxidases couple O₂ reduction with proton transport across the plasma membrane and, as a part of the respiratory chain, contribute to the generation of an electrochemical proton gradient. Compared with other structurally characterized members of the heme copper oxidases, the recently determined cbb₃ oxidase structure at 3.2 Å resolution revealed significant differences in the electron supply system, the proton conducting pathways and the coupling of O₂ reduction to proton translocation. In this paper, we present a detailed report on the key steps for structure determination. Improvement of the protein quality was achieved by optimization of the number of lipids attached to the protein as well as the separation of two cbb₃ oxidase isoenzymes. The exchange of n‐dodecyl‐β‐d ‐maltoside for a precisely defined mixture of two α‐maltosides and decanoylsucrose as well as the choice of the crystallization method had a most profound impact on crystal quality. This report highlights problems frequently encountered in membrane protein crystallization and offers meaningful approaches to improve crystal quality.     

Adaptation to Oxygen: ROLE OF TERMINAL OXIDASES IN PHOTOSYNTHESIS INITIATION IN THE PURPLE PHOTOSYNTHETIC BACTERIUM,RUBRIVIVAX GELATINOSUS*

The appearance of oxygen in the Earth''s atmosphere via oxygenic photosynthesis required strict anaerobes and obligate phototrophs to cope with the presence of this toxic molecule. Here we show that in the anoxygenic phototroph Rubrivivax gelatinosus, the terminal oxidases (cbb₃, bd, and caa₃) expand the range of ambient oxygen tensions under which the organism can initiate photosynthesis. Unlike the wild type, the cbb₃⁻/bd⁻ double mutant can start photosynthesis only in deoxygenated medium or when oxygen is removed, either by sparging cultures with nitrogen or by co-inoculation with strict aerobes bacteria. In oxygenated environments, this mutant survives nonphotosynthetically until the O₂ tension is reduced. The cbb₃ and bd oxidases are therefore required not only for respiration but also for reduction of the environmental O₂ pressure prior to anaerobic photosynthesis. Suppressor mutations that restore respiration simultaneously restore photosynthesis in nondeoxygenated medium. Furthermore, induction of photosystem in the cbb₃⁻ mutant led to a highly unstable strain. These results demonstrate that photosynthetic metabolism in environments exposed to oxygen is critically dependent on the O₂-detoxifying action of terminal oxidases.     

His92 and His110 selectively affect different heme centers of adrenal cytochrome b561

Adrenal cytochrome b₅₆₁ (cyt b₅₆₁), a transmembrane protein that shuttles reducing equivalents derived from ascorbate, has two heme centers with distinct spectroscopic signals and reactivity towards ascorbate. The His54/His122 and His88/His161 pairs furnish axial ligands for the hemes, but additional amino acid residues contributing to the heme centers have not been identified. A computational model of human cyt b₅₆₁ (Bashtovyy, D., Berczi, A., Asard, H., and Pali, T. (2003) Protoplasma 221, 31-40) predicts that His92 is near the His88/His161 heme and that His110 abuts the His54/His122 heme. We tested these predictions by analyzing the effects of mutations at His92 or His110 on the spectroscopic and functional properties. Wild type cytochrome and mutants with substitutions in other histidine residues or in Asn78 were used for comparison. The largest lineshape changes in the optical absorbance spectrum of the high-potential (b_H) peak were seen with mutation of His92; the largest changes in the low-potential (b_L) peak lineshape were observed with mutation of His110. In the EPR spectra, mutation of His92 shifted the position of the g = 3.1 signal (b_H) but not the g = 3.7 signal (b_L). In reductive titrations with ascorbate, mutations in His92 produced the largest increase in the midpoint for the b_H transition; mutations in His110 produced the largest decreases in ΔA₅₆₁ for the b_L transition. These results indicate that His92 can be considered part of the b_H heme center, and His110 part of the b_L heme center, in adrenal cyt b₅₆₁.     

Two conserved non-canonical histidines are essential for activity of the cbb 3-type oxidase in Rhodobacter capsulatus

Cytochrome cbb ₃ oxidase, a member of the heme–copper oxidase superfamily, catalyses the reduction of oxygen to water and generates a proton gradient. Cytochrome c oxidases are characterized by a catalytic subunit (subunit I) containing two hemes and one copper ion ligated by six invariant histidine residues, which are diagnostic of heme–copper oxidases in all type of the heme–copper oxidase superfamily. Alignments of the amino acid sequences of subunit I (FixN or CcoN) of the cbb ₃-type oxidases show that catalytic subunit also contains six non-canonical histidine residues that are conserved in all CcoN subunits of the cbb ₃ oxidase, but not the catalytic subunits of other members of heme–copper oxidases superfamily. The function of these six CcoN-specific conserved histidines of cbb ₃-type oxidase in R. capsulatus is unknown. To analyze the contribution of the two invariant histidines of CcoN, H300 and H394, in activity and assembly of the Rhodobacter capsulatus cbb ₃-type oxidase, they were substituted for valine and alanine, respectively by site-directed mutagenesis. H300V and H394A mutations were analyzed with respect to their activity and assembly. It was found that H394A mutation led to a defect in the assembly of both CcoP and CcoO in the membrane, which results in almost complete loss of activity and that although the H300V mutant is normally assembled in the membrane and retain their stability, its catalytic activity is significantly reduced when compared with wild-type oxidase.     

Heme/heme redox interaction and resolution of individual optical absorption spectra of the hemes in cytochrome bd from Escherichia coli

Cytochrome bd is a terminal component of the respiratory chain of Escherichia coli catalyzing reduction of molecular oxygen to water. It contains three hemes, b₅₅₈, b₅₉₅, and d. The detailed spectroelectrochemical redox titration and numerical modeling of the data reveal significant redox interaction between the low-spin heme b₅₅₈ and high-spin heme b₅₉₅, whereas the interaction between heme d and either hemes b appears to be rather weak. However, the presence of heme d itself decreases much larger interaction between the two hemes b. Fitting the titration data with a model where redox interaction between the hemes is explicitly included makes it possible to extract individual absorption spectra of all hemes. The α- and β-band reduced-minus-oxidized difference spectra agree with the data published earlier ([22] J.G. Koland, M.J. Miller, R.B. Gennis, Potentiometric analysis of the purified cytochrome d terminal oxidase complex from Escherichia coli, Biochemistry 23 (1984) 1051-1056., and [23] R.M. Lorence, J.G. Koland, R.B. Gennis, Coulometric and spectroscopic analysis of the purified cytochrome d complex of Escherichia coli: evidence for the identification of “cytochrome a₁” as cytochrome b₅₉₅, Biochemistry 25 (1986) 2314-2321.). The Soret band spectra show λ_max = 429.5 nm, λ_min ≈ 413 nm (heme b₅₅₈), λ_max = 439 nm, λ_min ≈ 400 ± 1 nm (heme b₅₉₅), and λ_max = 430 nm, λ_min = 405 nm (heme d). The spectral contribution of heme d to the complex Soret band is much smaller than those of either hemes b; the Soret/α (ΔA₄₃₀:ΔA₆₂₉) ratio for heme d is 1.6.     

Heme-heme and heme-ligand interactions in the di-heme oxygen-reducing site of cytochrome bd from Escherichia coli revealed by nanosecond absorption spectroscopy

Cytochrome bd is a terminal quinol:O₂ oxidoreductase of respiratory chains of many bacteria. It contains three hemes, b₅₅₈, b₅₉₅, and d. The role of heme b₅₉₅ remains obscure. A CO photolysis/recombination study of the membranes of Escherichia coli containing either wild type cytochrome bd or inactive E445A mutant was performed using nanosecond absorption spectroscopy. We compared photoinduced changes of heme d-CO complex in one-electron-reduced, two-electron-reduced, and fully reduced states of cytochromes bd. The line shape of spectra of photodissociation of one-electron-reduced and two-electron-reduced enzymes is strikingly different from that of the fully reduced enzyme. The difference demonstrates that in the fully reduced enzyme photolysis of CO from heme d perturbs ferrous heme b₅₉₅ causing loss of an absorption band centered at 435 nm, thus supporting interactions between heme b₅₉₅ and heme d in the di-heme oxygen-reducing site, in agreement with previous works. Photolyzed CO recombines with the fully reduced enzyme monoexponentially with τ ∼ 12 μs, whereas recombination of CO with one-electron-reduced cytochrome bd shows three kinetic phases, with τ ∼ 14 ns, 14 μs, and 280 μs. The spectra of the absorption changes associated with these components are different in line shape. The 14 ns phase, absent in the fully reduced enzyme, reflects geminate recombination of CO with part of heme d. The 14-μs component reflects bimolecular recombination of CO with heme d and electron backflow from heme d to hemes b in ∼ 4% of the enzyme population. The final, 280-μs component, reflects return of the electron from hemes b to heme d and bimolecular recombination of CO in that population. The fact that even in the two-electron-reduced enzyme, a nanosecond geminate recombination is observed, suggests that namely the redox state of heme b₅₉₅, and not that of heme b₅₅₈, controls the pathway(s) by which CO migrates between heme d and the medium.     

Spectroscopic and Functional Characterizations of Cyanobacterium Synechocystis PCC 6803 Mutants on and near the Heme Axial Ligand of Cytochrome b559 in Photosystem II

The functional role of cytochrome (cyt) b₅₅₉ in photosystem II (PSII) was investigated in H22Kα and Y18Sα cyt b₅₅₉ mutants of the cyanobacterium Synechocystis sp. PCC6803. H22Kα and Y18Sα cyt b₅₅₉ mutant carries one amino acid substitution on and near one of heme axial ligands of cyt b₅₅₉ in PSII, respectively. Both mutants grew photoautotrophically, assembled stable PSII, and exhibited the normal period-four oscillation in oxygen yield. However, both mutants showed several distinct chlorophyll a fluorescence properties and were more susceptible to photoinhibition than wild type. EPR results indicated the displacement of one of the two axial ligands to the heme of cyt b₅₅₉ in H22Kα mutant reaction centers, at least in isolated reaction centers. The maximum absorption of cyt b₅₅₉ in Y18Sα mutant PSII core complexes was shifted to 561 nm. Y18Sα and H22Kα mutant PSII core complexes contained predominately the low potential form of cyt b₅₅₉. The findings lend support to the concept that the redox properties of cyt b₅₅₉ are strongly influenced by the hydrophobicity and ligation environment of the heme. When the cyt b₅₅₉ mutations placed in a D1-D170A genetic background that prevents assembly of the manganese cluster, accumulation of PSII is almost completely abolished. Overall, our data support a functional role of cyt b₅₅₉ in protection of PSII under photoinhibition conditions in vivo.