Biochemical and biophysical studies on cytochrome c oxidase. XIX. An EPR study of the photodissociation of carboxycytochrome c oxidase in the presence of azide

1. The photodissociation reaction of the cytochrome c oxidase-CO compound in the presence of azide was studied by EPR at 15°K. Addition of CO in the dark to cytochrome c oxidase, partially reduced (2 electrons per 4 metal ions) in the presence of azide brings about a decrease in intensity of the azide-induced low-spin heme signal at g = 2.9, 2.2 and 1.67 and an increase in intensity of both the low-spin heme signal at g = 3 and the copper signal at g = 2. Subsequent illumination with white light at room temperature of this sample causes an enhancement of the azide-induced signal at g = 2.9, and a decrease in intensity of both signals at g = 3 and g = 2. It is shown that these changes in the EPR spectrum are reversible.

2. These results demonstrate that upon photodissociation, CO is replaced by azide wheras upon incubation in the dark CO expels azide from its binding site in cytochrome c oxidase.

3. Concomitantly with the binding of CO and dissociation of the azide molecule, and vice versa, electron redistributions occur as inferred from the changes in the intensity of the copper signal at g = 2.

4. The results are explained in a model of cytochrome c oxidase with either a common binding site (cytochrome a₃)^* for CO and azide or in a model with anti-cooperative interaction between two different sites of binding.

5. Similar types of experiments with cyanide instead of azide show that cyanide is more firmly bound to partially reduced cytochrome c oxidase than CO and azide. The affinity of ligands for partially reduced enzyme decreases in the sequence: cyanide, CO (dark), azide and CO (illuminated).     

Preparation and spectral characterization of the heme d1.apomyoglobin complex: an unusual protein environment for the substrate-binding heme of Pseudomonas cytochrome oxidase

The heme d1 prosthetic group isolated from Pseudomonas cytochrome oxidase combines with apomyoglobin to form a stable, optically well-defined complex. Addition of ferric heme d1 quenches apomyoglobin tryptophan fluorescence suggesting association in a 1:1 molar ratio. Optical absorption maxima for heme d1.apomyoglobin are at 629 and 429 nm before, and 632 and 458 nm after dithionite reduction; they are distinct from those of heme d1 in aqueous solution but more similar to those unobscured by heme c in Pseudomonas cytochrome oxidase. Cyanide, carbon monoxide and imidazole alter the spectrum of heme d1.apomyoglobin demonstrating axial coordination to heme d1 by exogeneous ligands. The cyanide-induced optical difference spectra exhibit isosbestic points, and a Scatchard-like analysis yields a linear plot with an apparent dissociation constant of 4.2 X 10(-5) M. However, carbon monoxide induces two absorption spectra with Soret maxima at 454 or 467 nm, and this duplicity, along with a shoulder that correlates with the latter before binding, suggests multiple carbon monoxide and possibly heme d1 orientations within the globin. The 50-fold reduction in cyanide affinity over myoglobin is more consistent with altered heme pocket interactions than the intrinsic electronic differences between the two hemes. However, stability of the heme d1.apomyoglobin complex is verified further by the inability to separate heme d1 from globin during dialysis and column chromatography in excess cyanide or imidazole. This stability, together with a comparison between spectra of ligand-free and -bound derivatives of heme d1-apomyoglobin and heme d1 in solution, implies that the prosthetic group is coordinated in the heme pocket through a protein-donated, strong-field ligand. Furthermore, the visible spectrum of heme d1.apomyoglobin varies minimally with ligand exchange, in contrast to the Soret, which suggests that much spectral information concerning heme d1 coordination in the oxidase is lost by interference from heme c absorption bands. A comparison of the absorption spectra of heme d1.apomyoglobin and Pseudomonas cytochrome oxidase, together with a critical examination of the previous axial ligand assignments from magnetic resonance techniques in the latter, implies that it is premature to accept the assignment of bishistidine heme d1 coordination in oxidized, ligand-free oxidase and other iron-isobacteriochlorin-containing enzymes.     

Carbon monoxide-driven reduction of ferric heme and heme proteins

Oxidized cytochrome c oxidase in a carbon monoxide atmosphere slowly becomes reduced as shown by changes in its visible spectra and its reactivity toward oxygen. The "auto-reduction" of cytochrome c oxidase by this procedure has been used to prepare mixed valence hybrids. We have found that this process is a general phenomenon for oxygen-binding heme proteins, and even for isolated hemin in basic aqueous solution. This reductive reaction may have physiological significance. It also explains why oxygen-binding heme proteins become oxidized much more slowly and appear to be more stable when they are kept under a CO atmosphere. Oxidized alpha and beta chains of human hemoglobin become reduced under CO much more slowly than does cytochrome c oxidase, where the CO-binding heme is coupled with another electron accepting metal center. By observing the reaction in both the forward and reverse direction, we have concluded that the heme is reduced by an equivalent of the water-gas shift reaction (CO + H2O----CO2 + 2e- + 2H+). The reaction does not require molecular oxygen. However, when the CO-driven reduction of cytochrome c oxidase occurs in the presence of oxygen, there is a competition between CO and oxygen for the reduced heme and copper of cytochrome alpha 3. Under certain conditions when both CO and oxygen are present, a peroxide adduct derived from oxygen reduction can be observed. This "607 nm complex," described in 1981 by Nicholls and Chanady (Nicholls, P., and Chanady, G. (1981) Biochim. Biophys. Acta 634, 256-265), forms and decays with kinetics in accord with the rate constants for CO dissociation, oxygen association and reduction, and dissociation of the peroxide adduct. In the absence of oxygen, if a mixture of cytochrome c and cytochrome c oxidase is incubated under a CO atmosphere, auto-reduction of the cytochrome c as well as of the cytochrome c oxidase occurs. By our proposed mechanism this involves a redistribution of electrons from cytochrome alpha 3 to cytochrome alpha and cytochrome c.     

Biochemical and biophysical studies on cytochrome c oxidase. XX. Reaction with sulphide.

1.Upon addition of sulphide to oxidized cytochrome c oxidase, a low-spin heme sulphide compound is formed with an EPR signal at gx = 2.54, gy = 2.23 and gz = 1.87. Concomitantly with the formation of this signal the EPR-detectable low-spin heme signal at g = 3 and the copper signal near g = 2 decrease in intensity, pointing to a partial reduction of the enzyme by sulphide. 2. The addition of sulphide to cytochrome c oxidase, previously reduced in the presence of azide or cyanide, brings about a disappearance of the azido-cytochrome c oxidase signal at gx = 2.9, gy = 2.2, and gz = 1.67 and a decrease of the signal at g = 3.6 of cyano-cytochrome c oxidase. Concomitantly the sulphide-induced EPR signal is formed. 3. These observations demonstrate that azide, cyanide and sulphide are competitive for an oxidized binding site on cytochrome c oxidase. Moreover, it is shown that the affinity of cyanide and sulphide for this site is greater than that of azide.     

The effect of mitochondrial energization on cytochrome c oxidase kinetics as measured at low temperatures. I. The reaction with carbon monoxide.

The kinetics of CO binding by the cytochrome c oxidase of pigeon heart mitochondria were studied as a function of membrane energization at temperatures from 180 to 280 degrees K in an ethylene glycol/water medium. Samples energized by ATP showed acceleration of CO binding compared to those untreated or uncoupled by carbonylcyanide p-trifluoromethyoxyphenylhydrazone but only at relatively low temperatures and high CO concentrations. Experiments using samples in a "mixed valency" (partially oxidized) state showed that the acceleration of ligand binding is not due to the formation of a partially oxidized state via reverse electron transport. It is concluded that in the deenergized state one CO molecule can be closely associated with the cytochrome a3 heme site without actually being bound to the heme iron; in the energized state, two or more ligand molecules can occupy this intermediate position. The change in the apparent ligand capacity of a region near the heme iron in response to energization is evidence for an interaction between cytochrome oxidase and the ATPase system. Furthermore, these results suggest a control mechanism for O2 binding.     

Electronic state of heme in cytochrome oxidase. I. Magnetic circular dichroism of the isolated enzyme and its derivatives.

Magnetic circular dichroism (MCD) spectra have been recorded for beef heart cytochrome oxidase and a number of its inhibitor complexes. The resting enzyme exhibits a derivate shape Faraday C term in the Soret region, characteristic of low spin ferric heme, which accounts for 50% of the total oxidase heme a. The remaining heme a (50%) is assigned to the high spin state. MCD temperature studies, comparison with the MCD spectra of heme a-imidazole model compounds, and ligand binding (cyanide, formate) studies are consistent with these spin state assignments in the oxidized enzyme. Furthermore, the ligand binding properties and correlations between optical and MCD parameters indicate that in the resting enzyme the low spin heme a is due solely to cytochrome a3+ and the high spin heme a to cytochrome a33+. The Soret MCD of the reduced protein is interpreted as th sum of two MCD curves: an intense, asymmetric MCD band very similar to that exhibited by deoxymyoglobin which we assign to paramagnetic high spin cytochrome a3(2+) and a weaker, more symmetric MCD contribution, which is attributed to diamagnetic low spin cytochrome a2+. Temperature studies of the Soret MCD intensity support this proposed spin state heterogeneity. Ligand binding (CO, CN-) to the reduced protein eliminates the intense MCD associated with high spin cytochrome a3(2+); however, the band associated with cytochrome a2+ is observed under these conditions as well as in a number of inhibitor complexes (cyanide, formate, sulfide, azide) of the partially reduced protein. The MCD spectra of oxidized, reduced, and inhibitor-complexed cytochrome oxidase show no evidence for heme-heme interaction via spectral parameters. This conclusion is used in conjunction with the fact that ferric, high spin heme exhibits weak MCD intensity to calculate the MCD spectra for the individual cytochromes of the oxidase as well as the spectra for some inhibitor complexes of cytochrome a3. The results are most simply interpreted using the model we have recently proposed to account for the electronic and magnetic properties of cytochrome (Palmer, G., Babcock, F.T., and Vcikery, L.E. (1976) Proc. Natl. Acad. Sci. U. S. A. 73, 2206-2210).     

A cytochrome bb'-type quinol oxidase in Bacillus subtilis strain 168.

The aerobic respiratory system of Bacillus subtilis 168 is known to contain three terminal oxidases: cytochrome caa(3), which is a cytochrome c oxidase, and cytochrome aa(3) and bd, which are quinol oxidases. The presence of a possible fourth oxidase in the bacterium was investigated using a constructed mutant, LUH27, that lacks the aa(3) and caa(3) terminal oxidases and is also deficient in succinate:menaquinone oxidoreductase. The cytochrome bd content of LUH27 can be varied by using different growth conditions. LUH27 membranes virtually devoid of cytochrome bd respired with NADH or exogenous quinol as actively as preparations containing 0.4 nmol of cytochrome bd/mg of protein but were more sensitive to cyanide and aurachin D. The reduced minus oxidized difference spectra of the bd-deficient membranes as well as absorption changes induced by CO and cyanide indicated the presence of a "cytochrome o"-like component; however, the membranes did not contain heme O. The results provide strong evidence for the presence of a terminal oxidase of the bb' type in B. subtilis. The enzyme does not pump protons and combines with CO much faster than typical heme-copper oxidases; in these respects, it resembles a cytochrome bd rather than members of the heme-copper oxidase superfamily. The genome sequence of B. subtilis 168 contains gene clusters for four respiratory oxidases. Two of these clusters, cta and qox, are deleted in LUH27. The remaining two, cydAB and ythAB, encode the identified cytochrome bd and a putative second cytochrome bd, respectively. Deletion of ythAB in strain LUH27 or the presence of the yth genes on plasmid did not affect the expression of the bb' oxidase. It is concluded that the novel bb'-type oxidase probably is cytochrome bd encoded by the cyd locus but with heme D being substituted by high spin heme B at the oxygen reactive site, i.e. cytochrome b(558)b(595)b'.     

Biochemical and biophysical studies on cytochrome c oxidase XVI. Circular dichroic study of cytochrome c oxidase and its ligand complexes

1. CD spectra of cytochrome c oxidase have been determined both in the absence and presence of the extrinsic ligands CO, NO, cyanide and azide.2. CO and NO affect the CD spectrum of cytochrome c oxidase in a similar way.3. Cyanide and azide also affect the CD spectrum of cytochrome c oxidase in a similar way, but distinctly different from CO and NO.4. From the CD spectra of the oxidized and reduced enzyme, in the presence and absence of extrinsic ligands, CD difference spectra (reduced minus oxidized) are calculated for the so-called cytochrome a and cytochrome a₃ moieties of the enzyme.5. These spectra are largely dependent on the extrinsic ligand used. It is therefore concluded that these spectra do not represent independent cytochrome a and cytochrome a₃ difference spectra, but that heme-heme interactions occur within the cytochrome c oxidase molecule, in such a way that binding of a ligand to one of the heme a groups of cytochrome c oxidase affects the spectral properties of the other heme a group.6. As a consequence, ligand-binding studies cannot give information as to the pre-existence of separate cytochrome a and cytochrome a₃ moieties in the absence of extrinsic ligands.     

The Content of Alternative Oxidase of Euglena Mitochondria is Increased by Growth in the Presence of Cyanide and is not Cytochrome o.

ABSTRACT A study of the effect of respiratory inhibitors on O₂ uptake of Euglena gracilis mitochondria, isolated from cells grown in the presence of cyanide or with ethanol as carbon source, was undertaken. The contents of cytochrome c oxidase and alternative oxidase were also determined. Inhibition of respiration by antimycin and cyanide was only partial and it was dependent on the oxidizable substrate used. Succinate oxidation was the most sensitive to cyanide whereas lactate oxidation was the most resistant. Cell growth in the presence of cyanide or with ethanol as carbon source brought about an enhanced content of alternative oxidase without a concomitant increase in cytochrome aa₃ content. However, a correlation between cyanide-resistant respiration and alternative oxidase content was not found. Analysis of heme types in mitochondrial membranes revealed the absence of heme O. The data suggest the presence of an inducible alternative oxidase in Euglena mitochondria which has high resistance to cyanide and contains heme B. A close relationship between Euglena alternative oxidase and bacterial quinol oxidases containing B-type heme is proposed.     

Interactions between heme d and heme b595 in quinol oxidase bd from Escherichia coli: a photoselection study using femtosecond spectroscopy

Femtosecond spectroscopy was performed on CO-liganded (fully reduced and mixed-valence states) and O(2)-liganded quinol oxidase bd from Escherichia coli. Substantial polarization effects, unprecedented for optical studies of heme proteins, were observed in the CO photodissociation spectra, implying interactions between heme d (the chlorin ligand binding site) and the close-lying heme b(595) on the picosecond time scale; this general result is fully consistent with previous work [Vos, M. H., Borisov, V. B., Liebl, U., Martin, J.-L., and Konstantinov, A. A. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 1554-1559]. Analysis of the data obtained under isotropic and anisotropic polarization conditions and additional flash photolysis nanosecond experiments on a mutant of cytochrome bd mostly lacking heme b(595) allow to attribute the features in the well-known but unusual CO dissociation spectrum of cytochrome bd to individual heme d and heme b(595) transitions. This renders it possible to compare the spectra of CO dissociation from reduced and mixed-valence cytochrome bd under static conditions and on a picosecond time scale in much more detail than previously possible. CO binding/dissociation from heme d is shown to perturb ferrous heme b(595), causing induction/loss of an absorption band centered at 435 nm. In addition, the CO photodissociation-induced absorption changes at 50 ps reveal a bathochromic shift of ferrous heme b(595) relative to the static spectrum. No evidence for transient binding of CO to heme b(595) after dissociation from heme d is found in the picosecond time range. The yield of CO photodissociation from heme d on a time scale of < 15 ps is found to be diminished more than 3-fold when heme b(595) is oxidized rather than reduced. In contrast to other known heme proteins, molecular oxygen cannot be photodissociated from the mixed-valence cytochrome bd at all, indicating a unique structural and electronic configuration of the diheme active site in the enzyme.     

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.     

Peculiarities of cyanide binding to the <Emphasis Type="Italic">ba</Emphasis><Subscript>3</Subscript>-type cytochrome oxidase from the thermophilic bacterium <Emphasis Type="Italic">Thermus thermophilus</Emphasis>

Cytochrome c oxidase of the ba ₃-type from Thermus thermophilus does not interact with cyanide in the oxidized state and acquires the ability to bind heme iron ligands only upon reduction. Cyanide complexes of the reduced heme a ₃ in cytochrome ba ₃ and in mitochondrial aa ₃-type cytochrome oxidase are similar spectroscopically, but the a ₃²⁺-CN complex of cytochrome ba ₃ is strikingly tight. Experiments have shown that the K _d value of the cytochrome ba ₃ complex with cyanide in the presence of reductants of the enzyme binuclear center does not exceed 10⁻⁸ M, which is four to five orders of magnitude less than the K _d of the cyanide complex of the reduced heme a ₃ of mitochondrial cytochrome oxidase. The tightness of the cytochrome ba ₃ complex with cyanide is mainly associated with an extremely slow rate of the ligand dissociation (k _off ≤ 10⁻⁷ sec⁻¹), while the rate of binding (k _on ∼ 10² M⁻¹·sec⁻¹) is similar to the rate observed for the mitochondrial cytochrome oxidase. It is proposed that cyanide dissociation from the cytochrome ba ₃ binuclear center might be hindered sterically by the presence of the second ligand molecule in the coordination sphere of Cu_B²⁺. The rate of cyanide binding with the reduced heme a ₃ does not depend on pH in the neutral area, but it approaches linear dependence on H⁺ activity in the alkaline region. Cyanide binding appears to be controlled by protonation of an enzyme group with pK _a = 8.75.     

The binding of carbon monoxide to cytochrome c oxidase.

The effect of CO on the optical absorbance spectrum of partially reduced cytochrome c oxidase has been studied. The changes at 432 and 590 nm suggest that the cytochrome alpha2/3+ - CO compound is formed preferentially and that concomitantly a second electron is taken up by the enzyme. From the CO-induced changes at 830 nm it is concluded that in the partially reduced enzyme addition of CO causes reoxidation of the copper component of cytochrome c oxidase. Addition of CO to partially reduced enzyme (2 electrons per 4 metal ions) also brings about a decrease in the intensities of electron paramagnetic resonance signals of high-spin heme iron near g = 6 and of the low-spin heme at g = 2.6. Concomitantly both the low-spin heme a signal at g = 3 and the copper signal at g = 2 increase in intensity. These results demonstrate that formation of the reduced diamagnetic cytochrome a3 - CO compound is accompanied by reoxidation of both the copper component detectable by electron paramagnetic resonance and possibly also by cytochrome a.     

Photodissociation of oxygenated cytochrome o(s) (Vitreoscilla) and kinetic studies of reassociation

Oxygenated cytochrome o(s) from Vitreoscilla was photodissociated by a laser flash but the quantum yield was low. The rebinding of oxygen to the ferrous cytochrome proceeded monophasically, and the second order rate constant was 7.8 X 10(7) M-1 s-1, the off rate constant 5.6 X 10(3) s-1, and the calculated dissociation constant for the oxygenated compound 7.2 X 10(-5) M at pH 7.3 and 25 degrees C. Rapid scanning spectroscopy revealed the formation of chytochrome o-O2 directly from ferrous chytochrome o and oxygen without any evidence for an intermediary formation of Compound D, another type of oxygenated chytochrome o. Photodissociation in solution containing CO/O2 mixtures resulted in rapid binding of oxygen followed by slow replacement by CO. This property as well as the photodissociability of chytochrome o-O2 suggests that the heme iron of the compound is in the ferrous state. In addition, the primary oxygen compound was fairly stable and did not decay further in the absence of CO, in marked contrast with that of mammalian cytochrome oxidase primary oxygen compound which rapidly decayed. This result suggests a possible role of this cytochrome as an oxygen carrier or storage.     

The effect of mitochondrial energization on cytochrome c oxidase kinetics as measured at low temperatures. I. The reaction with carbon monoxide

The kinetics of CO binding by the cytochrome c oxidase of pigeon heart mitochondria were studied as a function of membrane energization at temperatures from 180 to 280°K in an ethylene glycol/water medium. Samples energized by ATP showed acceleration of CO binding compared to those untreated or uncoupled by carbonylcyanide p-trifluoromethoxyphenylhydrazone but only at relatively low temperatures and high CO concentrations. Experiments using samples in a “mixed valency” (partially oxidized) state showed that the acceleration of ligand binding is not due to the formation of a partially oxidized state via reverse electron transport.It is concluded that in the deenergized state one CO molecule can be closely associated with the cytochrome a₃ heme site without actually being bound to the heme iron; in the energized state, two or more ligand molecules can occupy this intermediate position.The change in the apparent ligand capacity of a region near the heme iron in response to energization is evidence for an interaction between cytochrome oxidase and the ATPase system. Furthermore, these results suggest a control mechanism for O₂ binding.     

Electron-transfer processes in carboxy-cytochrome c oxidase after photodissociation of cytochrome a3 2+ . CO.

Under continuous illumination the CO binding curve of reduced carboxy-cytochrome c oxidase maintains the shape of the binding curve in the dark. The apparent dissociation constant calculated from the binding curves at various light intensities is a linear function of the light intensity. Marked differences are observed between the light-induced difference spectra of the fully reduced carboxy-cytochrome c oxidase and the mixed-valence carboxy-cytochrome c oxidase. These differences are enhanced in the presence of ferricyanide as an electron acceptor and are explained by partial oxidation of cytochrome a3 in the mixed-valence enzyme after photodissociation. Upon addition of CO to partially reduced formate cytochrome c oxidase (a2+a3 3+ . HCOOH) the cytochrome a3 2+. CO compound is formed completely with a concomitant oxidation of cytochrome a and the Cu associated with cytochrome a. During photodissociation of the CO compound the formate rebinds to cytochrome a3 and cytochrome a and its associated Cu are simultaneously reduced. These electron transfer processes are fully reversible since in the dark the a3 3+ . HCOOH compound is dissociated slowly with a concomitant formation of the a3 2+ . CO compound and oxidation of cytochrome a. When these experiments are carried out in the presence of cytochrome c, both cytochrome c and cytochrome a are reduced upon illumination of the mixed-valence carboxy-cytochrome c oxidase. In the dark both cytochrome c and cytochrome a are reoxidized when formate dissociates from cytochrome a3 and the a2+ 3 . CO compound is formed back. Thus, in this system we are able to reverse and to modulate the redox state of the different components of the final part of the respiratory chain by light.     

Proton-coupled structural changes upon binding of carbon monoxide to cytochrome cd1: a combined flash photolysis and X-ray crystallography study

We have investigated dynamic events after flash photolysis of CO from reduced cytochrome cd(1) nitrite reductase (NiR) from Paracoccus pantotrophus (formerly Thiosphaera pantotropha). Upon pulsed illumination of the cytochrome cd(1)-CO complex, at 460 nm, a rapid (<50 ns) absorbance change, attributed to dissociation of CO, was observed. This was followed by a biphasic rearrangement with rate constants of 1.7 x 10(4) and 2.5 x 10(3) s(-1) at pH 8.0. Both parts of the biphasic rearrangement phases displayed the same kinetic difference spectrum in the region of 400-660 nm. The slower of the two processes was accompanied by proton uptake from solution (0.5 proton per active site at pH 7.5-8.5). After photodissociation, the CO ligand recombined at a rate of 12 s(-1) (at 1 mM CO and pH 8.0), accompanied by proton release. The crystal structure of reduced cytochrome cd(1) in complex with CO was determined to a resolution of 1.57 A. The structure shows that CO binds to the iron of the d(1) heme in the active site. The ligation of the c heme is unchanged in the complex. A comparison of the structures of the reduced, unligated NiR and the NiR-CO complex indicates changes in the puckering of the d(1) heme as well as rearrangements in the hydrogen-bonding network and solvent organization in the substrate binding pocket at the d(1) heme. Since the CO ligand binds to heme d(1) and there are structural changes in the d(1) pocket upon CO binding, it is likely that the proton uptake or release observed after flash-induced CO dissociation is due to changes of the protonation state of groups in the active site. Such proton-coupled structural changes associated with ligand binding are likely to affect the redox potential of heme d(1) and may regulate the internal electron transfer from heme c to heme d(1).     

Interaction of bd-type quinol oxidase from Escherichia coli and carbon monoxide: Heme d binds CO with high affinity

Comparative studies on the interaction of the membrane-bound and detergent-solubilized forms of the enzyme in the fully reduced state with carbon monoxide at room temperature have been carried out. CO brings about a bathochromic shift of the heme d band with a maximum at 644 nm and a minimum at 624 nm, and a peak at 540 nm. In the Soret band, CO binding to cytochrome bd results in absorption decrease and minima at 430 and 445 nm. Absorption perturbations in the Soret band and at 540 nm occur in parallel with the changes at 630 nm and reach saturation at 3-5 microM CO. The peak at 540 nm is probably either beta-band of the heme d-CO complex or part of its split alpha-band. In both forms of cytochrome bd, CO reacts predominantly with heme d. Addition of high CO concentrations to the solubilized cytochrome bd results in additional spectral changes in the gamma-band attributable to the reaction of the ligand with 10-15% of low-spin heme b558. High-spin heme b595 does not bind CO even at high concentrations of the ligand. The apparent dissociation constant values for the heme d-CO complex of the membrane-bound and detergent-solubilized forms of the fully reduced enzyme are about 70 and 80 nM, respectively.     

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

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