Infrared evidence of cyanide binding to iron and copper sites in bovine heart cytochrome c oxidase. Implications regarding oxygen reduction

Infrared Spectroscopy: A New Frontier in Hematological Disease Diagnosis

Hematological diseases, due to their complex nature and diverse manifestations, pose significant diagnostic challenges in healthcare. The pressing need for early and accurate diagnosis has driven the exploration of novel diagnostic techniques. Infrared (IR) spectroscopy, renowned for its noninvasive, rapid, and cost-effective characteristics, has emerged as a promising adjunct in hematological diagnostics. This review delves into the transformative role of IR spectroscopy and highlights its applications in detecting and diagnosing various blood-related ailments. We discuss groundbreaking research findings and real-world applications while providing a balanced view of the potential and limitations of the technique. By integrating advanced technology with clinical needs, we offer insights into how IR spectroscopy may herald a new era of hematological disease diagnosis.

Crystallographic cyanide-probing for cytochrome c oxidase reveals structural bases suggesting that a putative proton transfer H-pathway pumps protons

Cytochrome c oxidase (CcO) reduces O2 in the O2-reduction site by sequential four-electron donations through the low-potential metal sites (CuA and Fea). Redox-coupled X-ray crystal structural changes have been identified at five distinct sites including Asp51, Arg438, Glu198, the hydroxyfarnesyl ethyl group of heme a, and Ser382, respectively. These sites interact with the putative proton-pumping H-pathway. However, the metal sites responsible for each structural change have not been identified, since these changes were detected as structural differences between the fully reduced and fully oxidized CcOs. Thus, the roles of these structural changes in the CcO function are yet to be revealed. X-ray crystal structures of cyanide-bound CcOs under various oxidation states showed that the O2-reduction site controlled only the Ser382-including site, while the low-potential metal sites induced the other changes. This finding indicates that these low-potential site-inducible structural changes are triggered by sequential electron-extraction from the low-potential sites by the O2-reduction site and that each structural change is insensitive to the oxidation and ligand-binding states of the O2-reduction site. Because the proton/electron coupling efficiency is constant (1:1), regardless of the reaction progress in the O2-reduction site, the structural changes induced by the low-potential sites are assignable to those critically involved in the proton pumping, suggesting that the H-pathway, facilitating these low-potential site-inducible structural changes, pumps protons. Furthermore, a cyanide-bound CcO structure suggests that a hypoxia-inducible activator, Higd1a, activates the O2-reduction site without influencing the electron transfer mechanism through the low-potential sites, kinetically confirming that the low-potential sites facilitate proton pump.

The therapeutic potential of mitochondrial toxins

When screening active compounds by phenotypic assays, we often encounter mitochondrial toxins, which are compounds that can affect mitochondrial functions. In normal cells, these toxins may have relatively low toxicity but can nonetheless show measurable effects even at low concentrations. On the other hand, in animals, mitochondrial toxins can exert severe toxicity. Mitochondrial toxins that act as inhibitors of respiratory chain complexes in oxidative phosphorylation (OXPHOS) are typically avoided during drug discovery efforts, as such compounds can directly promote lethal inhibition of pulmonary respiration. However, mitochondrial toxins could in fact have beneficial therapeutic effects. Anti-cancer strategies that target mitochondrial functions, particularly OXPHOS, have received increasing attention in recent years. In this review article we examine the significance of OXPHOS inhibitors as anti-cancer drug candidates and discuss compounds having microbial origins.

Cyanobiphenyl-spiropyrane and -hemicyanine conjugates for cyanide detection in organic/aqueous media through reverse ICT direction: Their practical applications

Cyanide is one of the most known toxic substances. It is used in many industries and threats human health and environment through releasing with wastewater. Therefore, it is very important to detect its accurate amount, rapidly. Herein, turn-on and turn-off fluorescence sensors of hybrid cyanobiphenyl-spiropyrane and -hemicyanine were developed for the detection of CN^- ions on the basis of nuchleophilic addition to indolium moiety. Detection behavior of the both probes toward a series of anions was investigated by means of fluorescence, UV-vis, NMR and TOF-MS techniques. The results obviously indicate that both probes show remarkable spectral changes and high selectivity toward CN^- with respect to other tested anions. Cyanide levels in water samples up to 0.208 μM could be quantitatively detected as practical application. A smartphone imaging application was successfully constructed for CN^- detection. Noticeably, production of cotton kids and PSF capsules revealed that the probe could be conveniently used for on-site measurement of cyanide without complicated instruments.

Radiation Damage Mechanisms of Chemotherapeutically Active Nitroimidazole Derived Compounds

Photoionization mass spectrometry, photoelectron-photoion coincidence spectroscopic technique, and computational methods have been combined to investigate the fragmentation of two nitroimidazole derived compounds: the metronidazole and misonidazole. These molecules are used in radiotherapy thanks to their capability to sensitize hypoxic tumor cells to radiation by "mimicking" the effects of the presence of oxygen as a damaging agent. Previous investigations of the fragmentation patterns of the nitroimidazole isomers (Bolognesi et al., 2016; Cartoni et al., 2018) have shown their capacity to produce reactive molecular species such as nitric oxide, carbon monoxide or hydrogen cyanide, and their potential impact on the biological system. The results of the present work suggest that different mechanisms are active for the more complex metronidazole and misonidazole molecules. The release of nitric oxide is hampered by the efficient formation of nitrous acid or nitrogen dioxide. Although both metronidazole and misonidazole contain imidazole ring in the backbone, the side branches of these molecules lead to very different bonding mechanisms and properties.

Nanozymes: Classification, Catalytic Mechanisms, Activity Regulation, and Applications

Because of the high catalytic activities and substrate specificity, natural enzymes have been widely used in industrial, medical, and biological fields, etc. Although promising, they often suffer from intrinsic shortcomings such as high cost, low operational stability, and difficulties of recycling. To overcome these shortcomings, researchers have been devoted to the exploration of artificial enzyme mimics for a long time. Since the discovery of ferromagnetic nanoparticles with intrinsic horseradish peroxidase-like activity in 2007, a large amount of studies on nanozymes have been constantly emerging in the next decade. Nanozymes are one kind of nanomaterials with enzymatic catalytic properties. Compared with natural enzymes, nanozymes have the advantages such as low cost, high stability and durability, which have been widely used in industrial, medical, and biological fields. A thorough understanding of the possible catalytic mechanisms will contribute to the development of novel and high-efficient nanozymes, and the rational regulations of the activities of nanozymes are of great significance. In this review, we systematically introduce the classification, catalytic mechanism, activity regulation as well as recent research progress of nanozymes in the field of biosensing, environmental protection, and disease treatments, etc. in the past years. We also propose the current challenges of nanozymes as well as their future research focus. We anticipate this review may be of significance for the field to understand the properties of nanozymes and the development of novel nanomaterials with enzyme mimicking activities.

Spontaneous Reduction of Copper(II) to Copper(I) at Solid-Liquid Interface

Oxidation and reduction reactions are of central importance in chemistry as well as vital to the basic functions of life and such chemical processes are generally brought about by oxidizing and reducing agents, respectively. Herein, we report the discovery of an interfacial reduction reaction (IRR) - without the use of any external reducing agent. In course of metal-ligand coordination, spontaneous reduction of Cu(II) to Cu(I) at a solid-liquid interface was observed-unlike in a liquid-phase reaction where no reduction of Cu(II) to Cu(I) was occurred. High-quality thin films of a new coordination network compound bearing a Fe(II)-CN-Cu(I) link were fabricated by IRR and employed for efficient electro-catalysis in the form of oxygen reduction reaction. Also, thermally activated reversible structural phase transition modulated the electron transport property in thin film. This work unveils the importance of chemical reactions at solid-liquid interfaces that can lead to the development of new functional thin film materials.

Observation of ligand transfer in ba3 oxidase from Thermus thermophilus: simultaneous FTIR detection of photolabile heme a3(2+)-CN and transient Cu(B)(2+)-CN complexes

FTIR and light-minus-dark FTIR spectroscopy have been employed to investigate the reaction of oxidized and fully reduced ba(3) oxidase with cyanide. The characterization of the structures of the bound CN(-) in the binuclear heme Fe-Cu(B) center is essential, given that a central issue in the function of ba(3) oxidase is the extent to which the partially reduced substrates interact with the two metals. In the reaction of oxidized ba(3) oxidase with cyanide the initially formed heme a(3)(3+)-C≡N-Cu(B)(2+) species with ν(CN) frequency at 2152 cm(-1) was replaced by a photolabile complex with a frequency at 2075 cm(-1) characteristic of heme a(3)(2+)-CN(-). Photolysis of the heme a(3)(2+)-CN(-) adduct produced a band at 2146 cm(-1) attributed to the formation of a transient Cu(B)(2+)-CN(-) complex. All forms are pH independent between pH 5.5-9.5 and at pD 7.5 indicating the absence of ionizable groups that influence the properties of the cyanide complexes. In contrast to previous reports, our results show that CN(-) does not bind simultaneously to both heme a(3)(2+) and Cu(B)(2+) to form the mixed valence a(3)(2+)-CN·Cu(B)(2+)CN species. The photolysis products of the heme a(3)(2+)-CN(-)/Cu(B)(2+) and heme a(3)(2+)-CN(-)/Cu(B)(1+) species are different suggesting that relaxation dynamics in the binuclear center following ligand photodissociation are dependent on the oxidation state of Cu(B).

Ligand trapping by cytochrome c oxidase: implications for gating at the catalytic center

Cytochrome c oxidase is a member of the heme-copper family of oxygen reductases in which electron transfer is linked to the pumping of protons across the membrane. Neither the redox center(s) associated with proton pumping nor the pumping mechanism presumably common to all heme-copper oxidases has been established. A possible conformational coupling between the catalytic center (Fe(a3)(3+)-Cu(B)(2+)) and a protein site has been identified earlier from ligand binding studies, whereas a structural change initiated by azide binding to the protein has been proposed to facilitate the access of cyanide to the catalytic center of the oxidized bovine enzyme. Here we show that cytochrome oxidase pretreated with a low concentration of azide exhibits a significant increase in the apparent rate of cyanide binding relative to that of free enzyme. However, this increase in rate does not reflect a conformational change enhancing the rapid formation of a Fe(a3)(3+)-CN-Cu(B)(2+) complex. Instead the cyanide-induced transition of a preformed Fe(a3)(3+)-N(3)-Cu(B)(2+) to the ternary complex of Fe(a3)(3+)-N(3) Cu(B)(2+)-CN is the most likely reason for the observed acceleration. Significantly, the slow rate of azide release from the ternary complex indicates that cyanide ligated to Cu(B) blocks a channel between the catalytic site and the solvent. The results suggest that there is a pathway that originates at Cu(B) and that, during catalysis, ligands present at this copper center control access to the iron of heme a(3) from the bulk medium.

Interaction of Cyanide with Enzymes Containing Vanadium, Manganese, Non-Heme Iron, and Zinc

Since the early discovery of Prussian Blue, cyano transition metal complexes have played a fundamental role in coordination chemistry. They represent important compounds with fascinating chemical and physical properties which turn them into valuable tools for both chemists and biologists. HCN as a precursor in prebiotic chemistry has gained interest in view of its polymers being involved in the formation of amino acids, purines, and orotic acid, a biosynthetic precursor of uracil. Clearly, the rapid formation of adenine by aqueous polymerization of HCN is one of the key discoveries in these experiments. The cyanide anion is usually toxic for most aerobic organisms because of its inhibitory effects on respiratory enzymes, but as a substrate it is an important source of carbon and nitrogen for microorganisms, fungi and plants. Most interestingly, the cyanide anion is a ligand of important metal-dependent biomolecules, such as the hydrogenases and the cobalt site in vitamin B12.

Investigations of vibrational coherence in the low-frequency region of ferric heme proteins

Femtosecond coherence spectroscopy is applied to a series of ferric heme protein samples. The low-frequency vibrational spectra that are revealed show dominant oscillations near 40 cm(-1). MbCN is taken as a typical example of a histidine-ligated, six-coordinate, ferric heme and a comprehensive spectroscopic analysis is carried out. The results of this analysis reveal a new heme photoproduct species, absorbing near 418 nm, which is consistent with the photolysis of the His(93) axial ligand. The photoproduct undergoes subsequent rebinding/recovery with a time constant of approximately 4 ps. The photoproduct lineshapes are consistent with a photolysis quantum yield of 75-100%, although the observation of a relatively strong six-coordinate heme coherence near 252 cm(-1) (assigned to nu(9) in the MbCN Raman spectrum) suggests that the 75% lower limit is much more likely. The phase and amplitude excitation profiles of the low-frequency mode at 40 cm(-1) suggest that this mode is strongly coupled to the MbCN photoproduct species and it is assigned to the doming mode of the transient penta-coordinated material. The absolute phase of the 40 cm(-1) mode is found to be pi/2 on the red side of 418 nm and it jumps to 3pi/2 as excitation is tuned to the blue side of 418 nm. The absolute phase of the 40 cm(-1) signal is not explained by the standard theory for resonant impulsive stimulated Raman scattering. New mechanisms that give a dominant momentum impulse to the resonant wavepacket, rather than a coordinate displacement, are discussed. The possibilities of heme iron atom recoil after photolysis, as well as ultrafast nonradiative decay, are explored as potential ways to generate the strong momentum impulse needed to understand the phase properties of the 40 cm(-1) mode.

Activated sludge inhibition by chemical stressors--a comprehensive study

The effects of shock loads of 1-chloro-2,4-dinitrobenzene (CDNB); cadmium; 1-octanol; 2,4-dinitrophenol (DNP); weakly complexed cyanide; pH 5, 9, and 11; and high ammonia levels on activated sludge biomass growth, respiration rate, flocculation, chemical oxygen demand removal, dewaterability, and settleability were studied. For all chemical shocks, except ammonia and pH, concentrations that caused 15, 25, and 50% respiration inhibition were used to provide a single pulse shock to sequencing batch reactor systems containing a nitrifying or non-nitrifying biomass. Cadmium and pH 11 shocks were most detrimental to all processes, followed by CDNB. The DNP and cyanide primarily affected respiration, while pH 5, pH 9, octanol, and ammonia did not affect the treatment process to a significant extent. A chemical source-process effect matrix is provided, which we believe will aid in the development of methods that prevent and/or attenuate the effects of toxic shock loads on activated sludge systems.

Photoacoustic characterization of protein dynamics following CO photodetachment from fully reduced bovine cytochrome c oxidase

We report a protein conformational change following carbon monoxide photodetachment from fully reduced bovine cytochrome c oxidase that is hypothesized to be associated with changes in ligand mobility through a dioxygen access channel in the protein. Although not resolved by earlier photoacoustic or optical studies on this adduct, utilization of slightly lower temperatures revealed a process with a kinetic lifetime of about 70 ns at 10 degrees C. We measure an enthalpy change of about 8 kcal/mol in 0.050 M HEPES buffer that becomes less endothermic (DeltaH approximately 2 kcal/mol) at higher ionic strength. The volume contraction of about -0.7 mL/mol associated with the process almost doubles in higher ionic strength buffer systems. Measurements of samples in phosphate buffer systems are similar and appear to display the same subtle ionic strength dependence. Both the isolation of this photoacoustic signal component and the possible dependence on ionic strength of the thermodynamic parameters derived from its analysis appear analogous to and consistent with prior photoacoustic results monitoring CO photodetachment from the camphor complex of cytochrome P-450. Accordingly, we consider a similar model in which a conformational change results in movement of an exposed charged group or groups towards the interior of the protein, out of contact with solvent, as in the closing of a salt bridge.

A Role for the Protein in Internal Electron Transfer to the Catalytic Center of Cytochrome c Oxidase

Internal electron transfer (ET) to heme a(3) during anaerobic reduction of oxidized bovine heart cytochrome c oxidase (CcO) was studied under conditions where heme a and Cu(A) were fully reduced by excess hexaamineruthenium. The data show that ET to heme a(3) is controlled by the state of ionization of a single protolytic residue with a pK(a) of 6.5 +/- 0.2. On the basis of the view that ET to the catalytic site is limited by coupled proton transfer, this pK(a) was attributed to Glu60 which is located at the entrance of the proton-conducting K channel on the matrix side of CcO. It is proposed that Glu60 controls proton entry into the channel. However, even with this channel open, there is the second factor that regulates ET, and this is ascribed to the rate of proton diffusion in the channel. In addition, it is concluded that proton transfer in the K channel is reversibly inhibited by the detergent Triton X-100. It is also found that the rate of ET to heme a(3) in the as-isolated resting enzyme and in CcO "activated" by reaction of fully reduced enzyme with O(2) is the same, implying that the catalytic sites of these two forms of oxidized enzyme are essentially identical.

Resonance Raman detection of the Fe2+-C-N modes in heme-copper oxidases: a probe of the active site

Resonance Raman spectroscopy has been employed to investigate the reduced cyano complexes of cytochrome aa(3) from bovine heart and Rhodobacter sphaeroides and of cytochrome bo(3) from E. coli. In the aa(3)-type oxidases, the frequency of the Fe-CN stretching mode is located at 468 cm(-1), and the bending Fe-C-N vibration, at 500 cm(-1). The fully reduced cytochrome bo(3)-CN complex gives rise to a stretching vibration at 468 cm(-1), a bending vibration at 491 cm(-1), and a stretching C-N vibration at 2037 cm(-1). The observed differences between aa(3) and bo(3) oxidases in the frequencies of the Fe-C-N group suggest a quantitative difference in the structure of the His-heme a(3)(2+)/Cu(B)(1+) and His-heme o(3)(2+)/Cu(B)(1+) binuclear pockets upon CN- binding.

Electrochemical, FT-IR and UV/VIS spectroscopic properties of the caa3 oxidase from T. thermophilus

The caa3-oxidase from Thermus thermophilus has been studied with a combined electrochemical, UV/VIS and Fourier-transform infrared (FT-IR) spectroscopic approach. In this oxidase the electron donor, cytochrome c, is covalently bound to subunit II of the cytochrome c oxidase. Oxidative electrochemical redox titrations in the visible spectral range yielded a midpoint potential of -0.01 +/- 0.01 V (vs. Ag/AgCl/3m KCl, 0.218 V vs. SHE') for the heme c. This potential differs for about 50 mV from the midpoint potential of isolated cytochrome c, indicating the possible shifts of the cytochrome c potential when bound to cytochrome c oxidase. For the signals where the hemes a and a3 contribute, three potentials, = -0.075 V +/- 0.01 V, Em2 = 0.04 V +/- 0.01 V and Em3 = 0.17 V +/- 0.02 V (0.133, 0.248 and 0.378 V vs. SHE', respectively) could be obtained. Potential titrations after addition of the inhibitor cyanide yielded a midpoint potential of -0.22 V +/- 0.01 V for heme a3-CN- and of Em2 = 0.00 V +/- 0.02 V and Em3 = 0.17 V +/- 0.02 V for heme a (-0.012 V, 0.208 V and 0.378 V vs. SHE', respectively). The three phases of the potential-dependent development of the difference signals can be attributed to the cooperativity between the hemes a, a3 and the CuB center, showing typical behavior for cytochrome c oxidases. A stronger cooperativity of CuB is discussed to reflect the modulation of the enzyme to the different key residues involved in proton pumping. We thus studied the FT-IR spectroscopic properties of this enzyme to identify alternative protonatable sites. The vibrational modes of a protonated aspartic or glutamic acid at 1714 cm-1 concomitant with the reduced form of the protein can be identified, a mode which is not present for other cytochrome c oxidases. Furthermore modes at positions characteristic for tyrosine vibrations have been identified. Electrochemically induced FT-IR difference spectra after inhibition of the sample with cyanide allows assigning the formyl signals upon characteristic shifts of the nu(C=O) modes, which reflect the high degree of similarity of heme a3 to other typical heme copper oxidases. A comparison with previously studied cytochrome c oxidases is presented and on this basis the contributions of the reorganization of the polypeptide backbone, of individual amino acids and of the hemes c, a and a3 upon electron transfer to/from the redox active centers discussed.

FTIR studies of the CO and cyanide adducts of fully reduced bovine cytochrome c oxidase

Photolysis spectra of the CO and cyanide adducts of reduced bovine cytochrome c oxidase have been studied by FTIR difference spectroscopy. Bound CO is predominantly in a single 1963 cm(-1) form whereas cyanide is bound in at least two forms (2058/2045 cm(-1)). These forms are pH-independent between pH 6.5 and 8.5, indicating that there is no titratable protonatable group that influences significantly their binding in this pH range. Photolysis spectra of the cyanide adduct have a positive band around 2090 cm(-1) in H(2)O due at least in part to free HCN and at 1880 cm(-1) in D(2)O due to free DCN. The frequency of the positive band around 2090 cm(-1), and its persistence in D(2)O media, raises the possibility that a transient cyanide-Cu(B) adduct also contributes to this signal, equivalent to the CO-Cu(B) species that is formed when CO is photolyzed. Photolysis produces changes throughout the 1000-1800 cm(-1) region. Reduced minus (reduced + CO) photolysis spectra in H(2)O exhibit a pH-independent and symmetrical peak/trough at 1749/1741 cm(-1). A related feature in homologous oxidases has been suggested to arise from a conserved glutamic acid. However, only around one-third of the feature is shifted to lower frequencies by incubation in D(2)O media, and an additional fraction is shifted if catalytic turnover occurs in D(2)O. Reduced minus (reduced + cyanide) photolysis spectra exhibit multiple features in H(2)O in this region with peaks at 1752, 1725, and 1708 cm(-1) and troughs at 1740, 1715, and 1698 cm(-1). Again, only a part of these features shift in D(2)O, even with catalytic turnover. A variety of additional H/D-sensitive features in the 1700-1000 cm(-1) region of the spectra can be discerned, one of which in cyanide photolysis spectra is tentatively assigned to a conserved tyrosine, Y244. Data are discussed in relation to the structure of the binuclear center and protonatable groups in its vicinity.

X-ray structure and the reaction mechanism of bovine heart cytochrome c oxidase

X-ray structure of bovine heart cytochrome c oxidase in the fully oxidized state shows a peroxide bridging between Fe2+ and Cu2+ in the O2 reduction site. The bond distances for Fe-O and Cu-O are 2.52 and 2.16 A, respectively. The structure is consistent with antiferromagnetic coupling between the two metals, which has long been known and to recent redox titration results [J. Biol. Chem. 274 (1999) 33403]. The trigonal planer coordination of Cu1+ in the O2 reduction site is consistent with the very weak interaction between Cu1+ and O2 bound at Fe2+ revealed by time-resolved resonance Raman investigations. One of the three histidine imidazoles coordinated to the Cu ion in the O2 reduction site fixes a tyrosine phenol group near the O2 reduction site with the direct covalent link between the two groups. The structure suggests that the phenol group is the site for donating protons to the bound O2. Redox-coupled conformational change in an extramembrane loop indicates that an aspartate (Asp51) in the loop apart from the O2 reduction site is the site for proton pumping.

Molecular Heme-Cyanide-Copper Bridged Assemblies: Linkage Isomerism, Trends in nu(CN) Values, and Relation to the Heme-a(3)/Cu(B) Site in Cyanide-Inhibited Heme-Copper Oxidases

Bovine heart cytochrome c oxidase and related heme copper oxidases are inhibited by cyanide, which binds at the binuclear heme-a(3)/Cu(B) site where dioxygen is reduced to water. To determine the mode of cyanide binding, heme-based binuclear complexes containing iron-cyanide-copper bridges in different oxidation states have been prepared by the reaction of [(py)(OEP)Fe(CN)] with Cu(II,I) precursors and structurally characterized by X-ray methods. Structures of two precursor complexes and two binuclear Cu(I)-CN-Cu(I) species are reported. The assembly [(py)(OEP)Fe-CN-Cu(Npy(3))](2+) has a nearly linear Fe(III)-CN-Cu(II) bridge containing low-spin Fe(III). The assemblies [(OEP)Fe-NC-Cu(MeNpy(2))](+) and [(OEP-CH(2)CN)Fe-NC-Cu(Npy(3))](+) exhibit the high-spin bridges Fe(III)-NC-Cu(I) and Fe(II)-NC-Cu(I), respectively. These are the first title bridges in these oxidation states. Bridge atom sequences are obtained from structural refinements of both linkage isomers; those for the reduced bridges are consistent with the soft-acid nature of Cu(I). Cyanide stretching frequencies respond to metal oxidation state and bridge geometry and, using data for solution and solid states, fall into the following ranges: Fe(III)-CN-Cu(II), 2120-2184 cm(-)(1) (11 examples); Fe(III)-NC-Cu(I), 2072-2100 cm(-)(1) (2 examples); Fe(II)-NC-Cu(I), 2099-2107 cm(-)(1) (1 example). These data are compared with nu(CN) values for the enzymes in different oxidation states. A nonlinear Fe(III)-CN-Cu(II) bridge (Cu-N-C = 150-160 degrees ) is consistent with the 2146-2152 cm(-)(1) range found for the fully oxidized enzymes. Bands that can be assigned with some certainty as Fe-CN vibrations in partially and fully reduced enzymes do not appear to correspond to Fe(III)-NC-Cu(I) and Fe(II)-NC-Cu(I) bridges but rather to Fe(II)-CN modes. The current work complements and extends our previous investigation (Scott and Holm, J. Am. Chem. Soc. 1994, 116, 11357) of linear and nonlinear Fe(III)-CN-Cu(II) bridges and is part of an investigation directed at providing a molecular basis of cyanide toxicity. (MeNpy(2) = bis(2-(2-pyridylethyl))methylamine; Npy(3) = tris(2-pyridylmethyl)amine; OEP = octaethylporphyrinate(2-), OEP-CH(2)CN = N-(cyanomethyl)octaethylporphyrinate(1-).)

Cyanide binding and active site structure in heme-copper oxidases: normal coordinate analysis of iron-cyanide vibrations of a3(2+)CN- complexes of cytochromes ba3 and aa3

The cyanide isotope-sensitive low-frequency vibrations of ferrous cyano complexes of cytochrome a3 are studied for cytochrome ba3 from Thermus thermophilus and cytochrome aa3 from bovine heart. Cyanide complexes of ba3 display three isotope sensitive frequencies at 512, 485, and 473 cm-1. The first is primarily an Fe-C stretching motion, whereas the lower wavenumber modes are bending motions. These iron-cyanide vibrations are independent of the redox levels of the other metal centers in the protein. On the other hand, the fully reduced bovine derivative complexed with cyanide gives rise to a bending vibration at 503 cm-1 and a stretching vibration at 469 cm-1. That is, the ordering of the stretching and bending frequencies is reversed from that of the bacterial protein. These results are analyzed by normal coordinate calculations to obtain comparative models for the binuclear O2 reducing site of the two proteins. We find that the observed frequencies are consistent with a linear Fe-C-N group and larger Fe-C stretching force constant (2.558 mdyn/A) for ba3 and a slightly bent Fe-C-N group (angle approximately 170 degrees) and a smaller Fe-C stretching force constant (2.335 mdyn/A) for aa3. Thus, there are significant differences in the interaction of cyanide with ferrous a3 in the two proteins that are most likely caused by a weaker proximal histidine interaction and stronger peripheral heme electron withdrawing effects in ba3. Possible sources of these protein-induced effects are discussed. Using the analysis developed here, comparison of the FeCN stretching and bending frequencies of the ferrous bovine a3-CN complex to those obtained from the ferric a3-CN complex suggests that upon conversion of the resting to the fully reduced protein, a conformational change occurs that constrains the ligand binding site.

Molecular Assemblies Containing Unsupported [Fe(III)-(&mgr;(2):eta(2)-RCO(2))-Cu(II)] Bridges

Formate is an inhibitor of cytochrome oxidases and also effects conversion of the bovine heart enzyme from the "fast" to the "slow" cyanide-binding form. The molecular basis of these effects is unknown; one possibility is that formate inserts as a bridge into the binuclear heme a(3)-Cu(B) site, impeding the binding of dioxygen or cyanide. Consequently, Fe-Cu-carboxylate interactions are a matter of current interest. We have initiated an examination of such interactions by the synthesis of the first examples of [Fe(III)-(&mgr;(2):eta(2)-RCO(2))-Cu(II)] bridges, minimally represented by Fe(III)-L + Cu(II)-O(2)CR --> [Fe(III)-(RCO(2))-Cu(II)] + L. A series of Cu(II) precursor complexes and solvate forms have been prepared and their structures determined, including [Cu(Me(5)dien)(O(2)CH)](+) (3), [Cu(Me(5)dien)(O(2)CH)(MeOH)](+) (4), [Cu(Me(6)tren)(O(2)CH)](+) (5), and [Cu(Me(5)dien)(OAc)](+) (6). [4](ClO(4)) was obtained in monoclinic space group P2(1)/n with a = 8.166(3) Å, b = 15.119(5) Å, c = 15.070(4) Å, beta = 104.65(2) degrees, and Z = 4. [5](ClO(4))/[6](ClO(4)) crystallize in orthorhombic space groups Pnma/Pna2(1) with a = 16.788(2)/14.928(5) Å, b = 9.542(1)/9.341(4) Å, c = 12.911(1)/12.554(4) Å, and Z = 4/4. In all cases, the carboxylate ligand is terminal and is bound in a syn orientation. Also prepared for the purpose of structural comparison was [Fe(OEP)(O(2)CH)], which occurred in monoclinic space group P2(1)/c with a = 13.342(2) Å, b = 13.621(2) Å, c = 19.333(2) Å, beta = 106.12(2) degrees, and Z = 4. The desired bridges were stabilized in the assemblies [(OEP)Fe(O(2)CH)Cu(Me(5)dien)(OClO(3))](+) (9), [(OEP)Fe(OAc)Cu(Me(5)dien)](2+) (10), and {(OEP)Fe[(O(2)CH)Cu(Me(6)tren)](2)}(3+) (11), which were prepared by the reaction of 3, 6, and 5, respectively, with [Fe(OEP)(OClO(3))] in acetone or dichloromethane. [9](ClO(4))/[10](ClO(4))(2).CH(2)Cl(2) crystallize in triclinic space group P&onemacr; with a = 9.016(3)/13.777(3) Å, b = 15.377(5)/13.847(3) Å, c = 19.253(5)/17.608(4) Å, alpha = 78.12(3)/96.82(3) degrees, beta = 86.30(4)/108.06(3) degrees, gamma = 76.23(3)/114.32(3) degrees, and Z = 2/2. Each assembly contains a [Fe(III)-(RCO(2))-Cu(II)] bridge but with the differing orientations anti-anti (9) and syn-anti (10, 11). The compound [11](ClO(4))(2)(SbF(6)) occurs in orthorhombic space group Pbcn with a = 12.517(6) Å, b = 29.45(1) Å, c = 21.569(8) Å, and Z = 4. Complex 11 is trinuclear; the Fe(III) site has two axial formate ligands with bond distances indicative of a high-spin configuration. Structural features of 9-11 are discussed and are considered in relation to the possible insertion of formate into the binuclear sites of two oxidases whose structures were recently determined. The present results contribute to the series of molecular assemblies with the bridge groups [Fe(III)-X-Cu(II)], X = O(2)(-), OH(-), and RCO(2)(-), all with a common high-spin heme, thereby allowing an examination of electronic structure as dependent on the bridging atom or group and bridge structure. (Me(5)dien = 1,1,4,7,7-pentamethyldiethylenetriamine; Me(6)tren = tris(2-(dimethylamino)ethyl)amine; OEP = octaethylporphyrinate(2-).)

Infrared and EPR studies on cyanide binding to the heme-copper binuclear center of cytochrome bo-type ubiquinol oxidase from Escherichia coli. Release of a CuB-cyano complex in the partially reduced state

Cyanide-binding to the heme-copper binuclear center of bo-type ubiquinol oxidase from Escherichia coli was investigated with Fourier transform-infrared and EPR spectroscopies. Upon treatment of the air-oxidized CN-inhibited enzyme with excess sodium dithionite, a 12C-14N stretching vibration at 2146 cm-1 characteristic of the FeO3+ C=N CuB2+ bridging structure was quickly replaced with another stretching mode at 2034.5 cm-1 derived from the FeO2+ C=N moiety. The presence of ubiquinone-8 or ubiquinone-1 caused a gradual autoreduction of the metal center(s) of the air-oxidized CN-inhibited enzyme and a concomitant appearance of a strong cyanide stretching band at 2169 cm-1. This 2169 cm-1 species could not be retained with a membrane filter (molecular weight cutoff = 10,000) and showed unusual cyanide isotope shifts and a D2O shift. These observations together with metal content analyses indicate that the 2169 cm-1 band is due to a CuB.CN complex released from the enzyme. The same species could be produced by anaerobic partial reduction of the CN-inhibited ubiquinol oxidase and, furthermore, of the CN-inhibited cytochrome c oxidase; but not at all from the fully reduced CN-inhibited enzymes. These findings suggest that there is a common intermediate structure at the binuclear center of heme-copper respiratory enzymes in the partially reduced state from which the CuB center can be easily released upon cyanide-binding.

Oxygen dependence of hepatocyte susceptibility to mitochondrial respiratory inhibitors

Most zone 3 specific hepatotoxins or their metabolites are mitochondrial toxins, and yet the susceptibility of hepatocytes to respiratory inhibitors at the low O2 concentrations found in zone 3 is not known. Potassium cyanide (CN) and antimycin A (AA) were found to be 5- and 2-fold more cytotoxic at 1% than at 95% O2, respectively. CN also inhibited the respiration of hepatocytes 36% more at 1% O2 than at 95% O2; however, AA inhibited the respiration to the same level at 1% and 95% O2. CN but not AA depleted ATP levels of hepatocytes more extensively at 1% than at 95% O2. The CN-trapping agents dihydroxyacetone, glyceraldehyde, alpha-ketoglutarate and pyruvate prevented CN-induced cytotoxicity more effectively at 95% O2 than at 1% O2. In contrast, thiosulfate was less effective in preventing CN toxicity at 95% than at 1% O2. Hepatocyte thiocyanate formation from CN and thiosulfate was much faster at 1% than at 95% O2, suggesting that rhodanese, the mitochondrial enzyme that forms thiocyanate from CN and thiosulfate, is more effective at 1% O2 than at 95% O2.

Kinetics and mechanism for the binding of HCN to cytochrome c oxidase

The kinetics of cyanide binding to cytochrome c oxidase were systematically studied as a function of [HCN], [oxidase], pH, ionic strength, temperature, type and concentration of solubilizing detergent, and monomer-dimer content of oxidase. On the basis of these results a minimum reaction mechanism is proposed in which the spectrally visible rapid and slow cyanide binding reactions are two consecutive first-order reactions, not parallel reactions with different conformers of cytochrome c oxidase. The fast reaction (k'obs) follows saturation type kinetics to form an HCN complex that subsequently undergoes a slow reaction (k'obs). The fast k'obs reaction is independent of ionic strength but is strongly dependent upon pH. Two pK values were evaluated from the bell-shaped rate versus pH profile; one is due to an ionizable group on the protein (pKa = 7.45), while the other is that of HCN (pKHCN = 9.15). Therefore, oxidase is reactive toward HCN only when the group on the protein is unprotonated. The slow k'obs reaction is not a reaction of oxidase with either CN- or HCN; in fact, the product formed by the fast k'obs reaction, the oxidase-HCN complex, still undergoes the slow k" process even if all of the excess KCN is removed. The apparent rate constant of the slower phase (k"obs) is independent of all the variations done in this study, and it probably corresponds to either a slow conformational change in the protein or a change in ligand coordination at one of the metal centers after HCN binds to the bimetallic center of oxidase. Based upon the bell-shaped pH dependence of the fast phase and the pH independence of the slow phase, the mechanism also predicts that a single conformer of cytochrome c oxidase can exhibit either monophasic or biphasic cyanide binding kinetics depending upon the pH. At either very low or very high pH, the two rates become comparable in magnitude, which makes the reaction appear to be monophasic even though both reactions still occur. The amount of monomeric or dimeric oxidase only slightly affects the magnitude of k'obs and k"obs values, and both processes are clearly present in both types of oxidase.

The pathway of CO binding to cytochrome c oxidase. Can the gateway be closed?

Addition of cyanide to the CO complex of cytochrome oxidase reduces the apparent photosensitivity of the Fe-CO bond. This effect is not seen with azide, or when cyanide is added to ferromyoglobin-CO. It is proposed that cyanide binds to CuB, and restricts the passage of CO out of the protein. This restriction favors geminate recombination of CO and ferrocytochrome a3, thereby lowering the apparent quantum yield for CO photolysis. The apparent Kd of cyanide for CuB is 15.4 mM. These data support a direct role for CuB in ligand binding by cytochrome c oxidase.

Peroxide-induced spectral perturbations of the 280-nm absorption band of cytochrome c oxidase

It is now widely believed that the first two electrons transferred to the dioxygen reduction site in cytochrome c oxidase (CcO) are not coupled to proton translocation. The activation of the pump cycle correlates with the binding of dioxygen to the binuclear center. In order to investigate conformational changes in CcO associated with the formation of dioxygen intermediates during the catalytic cycle of CcO, the effects of hydrogen peroxide binding to CcO have been examined using UV optical absorption and second derivative techniques. Our data indicates that in the presence low concentrations of H2O2 (2:1 molar ratio) an initial CcO-peroxide species is formed in which the 280-nm absorption band is red shifted. This red shift occurs prior to spectral changes associated with H2O2 binding to cytochrome a3. Upon addition of higher concentrations of H2O2 (> 10 equivalents of H2O2 per equivalent of CcO) oxidized CcO is converted to F-state enzyme with no corresponding shift at 280 nm. It is suggested that H2O2 initially binds to CuB2+ resulting in a conformational change in the enzyme giving rise to a red-shifted 280 nm band. The absence of any conformational changes in F-state enzyme is consistent with the lack of bridging interactions with CuB2+ in this intermediate.

Proton uptake by cytochrome c oxidase on reduction and on ligand binding

On reduction, cytochrome oxidase was found to take up 2.4 +/- 0.1 protons in the pH range 7.2-8.5, of which 2 are associated with the binuclear centre, and the remaining fractional proton with haem a/CuA. Ligation to oxidised cytochrome oxidase of the azide, formate, fluoride or cyanide anions is accompanied by uptake of one proton. In the case of the reduced enzyme, no protonation changes are observed on binding O2 (Hallén S. and Nilsson T. (1992) Biochemistry 31, 11853-11859) or CO. Cyanide binding to reduced oxidase is, in contrast, still accompanied by uptake of a proton. These findings are discussed in terms of our previously-published proposal for the ligand chemistry of the binuclear site. The results overall suggest a principle of electroneutrality of redox and ligand state changes of the binuclear centre, with charge compensations provided only by protonation reactions.

Slow ('resting') forms of mitochondrial cytochrome c oxidase consist of two kinetically distinct conformations of the binuclear CuB/a3 centre--relevance to the mechanism of proton translocation

We have purified slow ('resting') cytochrome oxidase from bovine heart, free of contamination with fast ('pulsed') enzyme. This form of the enzyme shows two kinetic phases of reduction of haem a3 by dithionite (k = 0.020 +/- 0.005 s-1 and k = 0.005 +/- 0.002 s-1). The presence of ligands that bind to the oxidized or reduced binuclear centre (formate or carbon monoxide respectively) has no effect on these rates. Varying the dithionite concentration also has no effect on either phase, although at low dithionite concentrations a lag phase is observed as the rate of haem a reduction is slower. The results are consistent with a model for reduction of the slow enzyme where the rate of electron transfer to the binuclear centre is the limiting step, rather than an equilibrium model where the haem a3 redox potential is low. Increasing the pH decreases the rate of the slower phase of dithionite reduction, but has no effect on the faster phase. EPR studies show that the slow phase (only) correlates with the disappearance of the g' = 12/g' = 2.95 signals, with the same pH dependence; again the presence of formate has no effect on these results. Deconvolution of the oxidized optical spectra shows that the enzyme reduced in the slow phase has a blue-shifted Soret band, relative to that reduced in the faster phase. Incubation of the oxidized enzyme at high pH causes a line-broadening of both the g' = 12 and g' = 2.95 EPR signals with no obvious effect on the amount of signal. The results are interpreted in a model where the presence of a carboxylate bridge between haem a3 and CuB defines the slow enzyme. It is suggested that the two rates of dithionite reduction are the result of different ligation to CuB--where water is the ligand the binuclear centre is FeIV/CuI (EPR-silent) and where hydroxide is the ligand the binuclear centre is FeIII/CuII (g' = 12/g' = 2.95 EPR signals).

Structure of the heme-copper binuclear center of the cytochrome bo complex of Escherichia coli: EPR and Fourier transform infrared spectroscopic studies

The cytochrome bo complex is a terminal quinol oxidase in the aerobic respiratory chain of Escherichia coli and functions as a redox-coupled proton pump. To clarify the structural differences of the binuclear reaction center between the cytochrome bo complex and the mitochondrial cytochrome c oxidase, a combined study using EPR and Fourier transform infrared spectroscopies was carried out. The EPR spectrum of the highly purified cytochrome bo complex in the air-oxidized state showed a broad EPR signal (peak g* = 3.7) from an integer spin system. This confirms the existence of the spin-spin exchange-coupled binuclear site, in which the Feo3+ and CuB2+ centers were bridged by an unknown ligand (X). Binding of azide at the binuclear site as an ionic modulator weakened the strength of the spin-spin exchange coupling and thus caused a narrowing of the broad EPR signal. Binding of another modulator, formate, at the binuclear site caused the formation of EPR signals at g' = 12 and 2.7, which are very similar to those observed for cytochrome c oxidase. Cyanide replaced the bridging ligand (X) to form an Feo(3+)-C-N-CuB2+ structure in which strong spin-spin exchange coupling is expected, leading to a complete EPR-invisible state. Infrared evidence (a 2146 cm-1 C-N stretching band for the cyanide complex and a 2041 cm-1 azide antisymmetric stretching band for the azide complex) supported the theory that these ligands form bridging structures at the binuclear center, as previously observed for cytochrome c oxidase.(ABSTRACT TRUNCATED AT 250 WORDS)

X-ray absorption spectroscopy of oriented cytochrome oxidase

The polarized X-ray absorption spectra of the copper, iron and zinc sites of mitochondrial cytochrome oxidase in oriented membrane multilayers have been examined. The copper X-ray absorption edge spectra indicate the presence of a tetragonal copper, which we assign as CuB, oriented with the long axis approximately orthogonal to the membrane normal. We have also detected the presence of a relatively long (2.6 A) Cu-S or Cu-Cl interaction, which we assign to a copper-thioether (probably Met210) coordination at the CuA site, with the bond oriented along the membrane normal. The coordination of the zinc, the iron and the CuB heme a3 binuclear site are discussed.

Stoichiometry and redox behaviour of metals in cytochrome-c oxidase

The early observation of extra copper in preparations of cytochrome-c oxidase has recently lead to a renewed interest in its stoichiometry and possible redox function. In various, pure preparations (heme A contents close to the theoretical value of 9.79 nmol/mg protein for the 13-subunit bovine enzyme) protein-related metal stoichiometries of 3 Cu, 2 Fe, 1 Zn, 1 Mg/monomer with M(r) 204266 were determined. Despite the presence of five potential redox metal ions, reductive and reoxidative titrations indicate the presence of only four one-electron-accepting/donating species in the ligand-free enzyme. Participation of two copper ions in a binuclear copper site acting as one-electron acceptor may explain both the observed copper stoichiometry and the redox behaviour. The homology of the C-terminal sequence of subunit II with one of the copper-binding sites in nitrous-oxide reductases provides possible ligands for complexing two copper ions in a binuclear center.

Probing heart cytochrome c oxidase structure and function by infrared spectroscopy

IR spectra directly probe specific vibrators in bovine heart cytochrome c oxidase, yielding quantitative as well as qualitative information on structures and reactions at these vibrators. C-O IR spectra reveal that CO binds to Fe2+ a3 as two conformers each in isolated immobile environments sensitive to Fea and/or CuA oxidation state but remarkably insensitive to pH, medium, anesthetics, and other factors that affect activity. C-N IR spectra reveal that the one CN- that binds to fully and partially oxidized enzyme can be in three different structures. These structures vary in relative amounts with redox level, thereby reflecting dynamic electron exchange among Fea, CuA, and CuB with associated changes in protein conformation of likely significance in O2 reduction and H(+)-pumping. Azide IR spectra also reflect redox-dependent long-range effects. The amide I IR bands, due to C-O vibrators of peptide linkages and composed of multiple bands derived from different secondary structures, reveal high levels of alpha-helix (approximately 60%) and subtle changes with redox level and exposure to anesthetics. N2O IR spectra reveal that these anesthetic molecules at clinically relevant levels occupy three sites of different polarity within the enzyme as the enzyme is reversibly, but only partially, inhibited.

Current issues in the chemistry of cytochrome c oxidase

Some contemporary issues relevant to the chemistry of mammalian cytochrome c oxidase are discussed. These include the optical properties of heme A and the spectroscopic consequences of the differences in side-chain substitution compared to heme B; a common fallacy concerning the electrostatic exchange interaction between cytochrome a3 and CuB; the question of the number and location of the copper components of the enzyme; and the mode of binding of ligands such as cyanide and azide.

Cytochrome caa3 from the thermophilic bacterium Thermus thermophilus: a member of the heme-copper oxidase superfamily

The subject of this short review is the cytochrome c oxidase (caa3) from the thermophilic bacterium Thermus thermophilus. First, some of the extensive physical and enzymological results obtained with this enzyme are reviewed, and two experiments are described, involving isotope substitutions in combination with Mössbauer and ENDOR spectroscopies, which have provided novel insight into the active sites of the enzyme. Second, we summarize recent molecular genetic work showing that Thermus cytochrome caa3 is a bona fide member of the superfamily of heme-copper oxidases. Finally, we present a rough three-dimensional model and speculate about certain features of the metal-binding sites.

Light-induced structural changes in cytochrome c oxidase. Measurements of electrogenic events and absorbance changes

We have investigated flash-induced electrogenic events and absorbance changes in cytochrome c oxidase in the absence of dioxygen and carbon monoxide. Electrogenic events were studied using a Teflon-bound layer of cytochrome c oxidase oriented in a phospholipid monolayer. Absorbance changes were observed exclusively in partly reduced cytochrome c oxidase; the largest changes were found in the one-electron-reduced species. Electrogenic events were detected in all reduction states of the enzyme. Both types of experiments displayed a rapid (< 0.5 microseconds) event followed by a biphasic relaxation. The time constants of the relaxation were 6 +/- 2 microseconds and 70 +/- 10 microseconds in the electrogenicity, and 9 +/- 3 microseconds in the absorbance changes (at approximately 22 degrees C). The kinetic absorbance difference spectrum was consistent with that of reduced minus oxidized haem. The experimental results are discussed in terms of structural changes in the vicinity of cytochrome a3. These changes may play an important role in all studies that involve flash photolysis of cytochrome c oxidase-ligand complexes.

Ligand-binding properties and heterogeneity of cytochrome bo from Escherichia coli

Cyanide and formate induce spectral changes in E. coli cytochrome bo which are similar to those induced in bovine heart cytochrome-c oxidase (cytochrome aa3). Cyanide induces a red shift of 6 nm in the Soret band, whereas formate induces a blue shift of 2 nm. Cytochrome bo as purified shows multiphasic cyanide-binding kinetics. At least three phases can be seen with rate constants of 16, 1 and 0.1 M-1 s-1, respectively, at pH 7 and 20 degrees C. The enzyme after redox cycling ('pulsing') or in situ in E. coli membranes shows essentially monophasic binding with a rate constant of 15 M-1 s-1. Further evidence of heterogeneity in the enzyme as prepared comes from formate binding, which also shows at least three phases (rate constants of 1.4, 0.2 and 0.01 M-1 s-1, respectively, at pH 5 and 20 degrees C). The fast phase of cyanide binding is eliminated in less than 2 min by incubation with 40 mM formate, but the intermediate phase is unaffected by incubation for 3.5 h with 40 mM formate. Thus, the subpopulation that causes the fast phase of cyanide binding also causes the fast phase of formate binding. Formate-ligated cytochrome bo has similar cyanide-binding kinetics to the subpopulation that causes the slow phase of cyanide binding in cytochrome bo as prepared. It appears, from all this, that the subpopulations responsible for the fast and slow phase of cyanide binding are analogous to the 'fast' and 'slow' forms, respectively, of cytochrome aa3.(ABSTRACT TRUNCATED AT 250 WORDS)

A new spectral intermediate in cyanide binding with the oxidized cytochrome c oxidase

Reaction of cyanide with oxidized cytochrome c oxidase at a low concentration of the ligand and pH > 8 reveals an initial phase, not reported earlier, associated with a small blue shift of the absorption spectrum, which is followed by a conventional red shift of the heme alpha(3+)3. The initial blue shift resembles the spectral changes induced under the same conditions by low concentrations of azide and it is not observed in the presence of 0.3 mM azide. It is suggested that, similarly to NO, cyanide and HN3 cannot only bind to heme alpha 3 but to Cu(2+)B as well, perturbing the spectrum of alpha(3+)3 indirectly. A rapid binding to Cu(2+)B could provide the long-sought intermediate in the cyanide reaction with heme alpha(3+)3, the existence of which is implied by the Michaelis-Menten type kinetics of the latter process.

Single crystals of bovine heart cytochrome c oxidase at fully oxidized resting, fully reduced and CO-bound fully reduced states are isomorphous with each other

Fully reduced and CO-bound fully reduced forms of cytochrome c oxidase from beef heart muscle were crystallized in the presence of sodium ascorbate under N2 or CO atmosphere. Hexagonal bipyramidal and tetragonal crystals were obtained for both forms depending on buffer species. The hexagonal bipyramidal crystals, as large as 0.6 mm in the largest dimension, diffracted X-rays at 7 A resolution, showing an identical space group and cell dimension, P6(2) or P6(4) and a = b = 209 A, c = 283 A, respectively. These parameters coincide with those for crystals of the fully oxidized resting enzyme. This result suggests that a large conformational change, like a subunit arrangement, is not induced by the redox change and/or binding of CO (and possibly O2) to heme a3.

Spectroscopic and genetic evidence for two heme-Cu-containing oxidases in Rhodobacter sphaeroides

It has recently become evident that many bacterial respiratory oxidases are members of a superfamily that is related to the eukaryotic cytochrome c oxidase. These oxidases catalyze the reduction of oxygen to water at a heme-copper binuclear center. Fourier transform infrared (FTIR) spectroscopy has been used to examine the heme-copper-containing respiratory oxidases of Rhodobacter sphaeroides Ga. This technique monitors the stretching frequency of CO bound at the oxygen binding site and can be used to characterize the oxidases in situ with membrane preparations. Oxidases that have a heme-copper binuclear center are recognizable by FTIR spectroscopy because the bound CO moves from the heme iron to the nearby copper upon photolysis at low temperature, where it exhibits a diagnostic spectrum. The FTIR spectra indicate that the binuclear center of the R. sphaeroides aa3-type cytochrome c oxidase is remarkably similar to that of the bovine mitochondrial oxidase. Upon deletion of the ctaD gene, encoding subunit I of the aa3-type oxidase, substantial cytochrome c oxidase remains in the membranes of aerobically grown R. sphaeroides. This correlates with a second wild-type R. sphaeroides is grown photosynthetically, the chromatophore membranes lack the aa3-type oxidase but have this second heme-copper oxidase. Subunit I of the heme-copper oxidase superfamily contains the binuclear center. Amino acid sequence alignments show that this subunit is structurally very highly conserved among both eukaryotic and prokaryotic species. The polymerase chain reaction was used to show that the chromosome of R. sphaeroides contains at least one other gene that is a homolog of ctaD, the gene encoding subunit I of the aa3-type cytochrome c oxidase.(ABSTRACT TRUNCATED AT 250 WORDS)