Observation of a novel transient ferryl complex with reduced CuB in cytochrome c oxidase

The reaction between mixed-valence (MV) cytochrome c oxidase from beef heart with H2O2 was investigated using the flow-flash technique with a high concentration of H2O2 (1 M) to ensure a fast bimolecular interaction with the enzyme. Under anaerobic conditions the reaction exhibits 3 apparent phases. The first phase (tau congruent with 25 micros) results from the binding of one molecule of H2O2 to reduced heme a3 and the formation of an intermediate which is heme a3 oxoferryl (Fe4+=O2-) with reduced CuB (plus water). During the second phase (tau congruent with 90 micros), the electron transfer from CuB+ to the heme oxoferryl takes place, yielding the oxidized form of cytochrome oxidase (heme a3 Fe3+ and CuB2+, plus hydroxide). During the third phase (tau congruent with 4 ms), an additional molecule of H2O2 binds to the oxidized form of the enzyme and forms compound P, similar to the product observed upon the reaction of the mixed-valence (i.e., two-electron reduced) form of the enzyme with dioxygen. Thus, within about 30 ms the reaction of the mixed-valence form of the enzyme with H2O2 yields the same compound P as does the reaction with dioxygen, as indicated by the final absorbance at 436 nm, which is the same in both cases. This experimental approach allows the investigation of the form of cytochrome c oxidase which has the heme a3 oxoferryl intermediate but with reduced CuB. This state of the enzyme cannot be obtained from the reaction with dioxygen and is potentially useful to address questions concerning the role of the redox state in CuB in the proton pumping mechanism.     

Oxygenation of carbon monoxide by bovine heart cytochrome c oxidase

Cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1), as the terminal enzyme of the mammalian mitochondrial electron transport chain, has long been known to catalyze the reduction of dioxygen to water. We have found that when reductively activated in the presence of dioxygen, the enzyme will also catalyze the oxidation of carbon monoxide to its dioxide. Two moles of carbon dioxide is produced per mole of dioxygen, and similar rates of production are observed for 1- and 2-electron-reduced enzyme. If 13CO and O2 are used to initiate the reaction, then only 13CO2 is detected as a product. With 18O2 and 12CO, only unlabeled and singly labeled carbon dioxide are found. No direct evidence was obtained for a water-gas reaction (CO + H2O----CO2 + H2) of the oxidase with CO. The CO oxygenase activity is inhibited by cyanide, azide, and formate and is not due to the presence of bacteria. Studies with scavengers of partially reduced dioxygen show that catalase decreases the rate of CO oxygenation.     

A new approach for studying fast biological reactions involving dioxygen: the reaction of fully reduced cytochrome c oxidase with O2

We describe a new method for studying rapid biological reactions involving dioxygen. This approach is based on the photolysis of a synthetic caged dioxygen carrier, which produces dioxygen on a fast time scale. The method was used to investigate the reduction of dioxygen to water by cytochrome c oxidase at room temperature following photolysis of a (mu-peroxo)(mu-hydroxo)bis[bis(bipyridyl)c obalt(III)] complex. The fact that dioxygen is generated in situ on a nanosecond or faster time scale avoids potential complications related to the fate of photodissociated CO in a conventional CO flow-flash experiment. The cobalt complex is stable at room temperature under anaerobic conditions and releases dioxygen upon irradiation at 355 nm with a quantum yield of 0.04. The complex does not react with reduced cytochrome oxidase or its reducing agents within the mixing time of the experiment, and its photoproducts do not interfere with the kinetics of the dioxygen reduction. The oxidation of the reduced cytochrome oxidase was monitored between 500 and 750 nm using a gated optical spectrometric multichannel analyzer following photodissociation of the cobalt complex. The data were analyzed using singular value decomposition and global exponential fitting, and two apparent lifetimes (380 +/- 50 micros and 1.7 +/- 0.2 ms) were resolved and compared to results from a conventional CO flow-flash experiment. The results show that approximately 90 microM dioxygen can be generated upon a single laser pulse and that this approach can be used to study other fast biological reactions involving O(2).     

The structure of the paramagnetic oxygen intermediate in the cytochrome c oxidase reaction.

A paramagnetic intermediate with an unusual e.p.r. spectrum is formed when fully reduced cytochrome c oxidase is allowed to react with dioxygen at 173 K. The effect on the e.p.r. spectrum of using dioxygen enriched in 17O was investigated. These experiments show that an oxygen atom derived from dioxygen is bound to Cu2+ in the intermediate. The e.p.r. parameters can be explained in terms of a weak antiferromagnetic interaction (J approximately equal to 10 cm-1) between Cu2+B and cytochrome a3 in the low-spin ferryl ion state. It is suggested that an OH- ion bound to Cu2+B is hydrogen bonded to the oxygen atom of the ferryl ion in cytochrome a3.     

Interactions of the anesthetic nitrous oxide with bovine heart cytochrome c oxidase. Effects on protein structure, oxidase activity, and other properties

The interactions of nitrous oxide with cytochrome c oxidase isolated from bovine heart muscle have been investigated in search of an explanation for the inhibition of mitochondrial respiration by the inhalation anesthetic. Oxidase activity of the isolated enzyme is partially and reversibly reduced by nitrous oxide. N2O molecules are shown by infrared spectroscopy to occupy sites within the oxidase. Occupancy of sites within the protein by N2O has no observed effects on visible Soret spectra or on the O2 reaction site; no evidence is found for N2O serving as a ligand to a metal. The anesthetic does not substitute for O2 as an oxygen atom donor in either the cytochrome c oxidase or carbon monoxide dioxygenase reactions catalyzed by the enzyme. N2O appears to affect oxidase activity by reducing the rate of electron transfer from cytochrome c to the O2 reaction site rather than by interfering directly with the reduction of O2 to water. Cytochrome c oxidase represents a target site for nitrous oxide and possibly other anesthetics, and the inhibition of oxidase activity may contribute significantly to the anesthetic and/or toxic effects of these substances.     

Primary intermediate in the reaction of mixed-valence cytochrome c oxidase with oxygen

The reaction of dioxygen with mixed-valence cytochrome c oxidase was followed in a rapid-mixing continuous-flow apparatus. The optical absorption difference spectrum and a kinetic analysis confirm the presence of the primary oxygen intermediate in the 0-100-microseconds time window. The resonance Raman spectrum of the iron-dioxygen stretching mode (568 cm-1) supplies evidence that the degree of electron transfer from the iron atom to the dioxygen is similar to that in oxy complexes of other heme proteins. Thus, the Fe-O2 bond does not display any unique structural features that could account for the rapid reduction of dioxygen to water. Furthermore, the frequency of the iron-dioxygen stretching mode is the same as that of the primary intermediate in the fully reduced enzyme, indicating that the oxidation state of cytochrome a plays no role in controlling the initial properties of the oxygen binding site.     

Time-resolved optical absorption studies of cytochrome oxidase dynamics

Time-resolved spectroscopic studies in our laboratory of bovine heart cytochrome c oxidase dynamics are summarized. Intramolecular electron transfer was investigated upon photolysis of CO from the mixed-valence enzyme, by pulse radiolysis, and upon light-induced electron injection into the cytochrome c/cytochrome oxidase complex from a novel photoactivatable dye. The reduction of dioxygen to water was monitored by a gated multichannel analyzer using the CO flow-flash method or a synthetic caged dioxygen carrier. The pH dependence of the intermediate spectra suggests a mechanism of dioxygen reduction more complex than the conventional unidirectional sequential scheme. A branched model is proposed, in which one branch produces the P form and the other branch the F form. The rate of exchange between the two branches is pH-dependent. A cross-linked histidine-phenol was synthesized and characterized to explore the role of the cross-linked His-Tyr cofactor in the function of the enzyme. Time-resolved optical absorption spectra, EPR and FTIR spectra of the compound generated after UV photolysis indicated the presence of a radical residing primarily on the phenoxyl ring. The relevance of these results to cytochrome oxidase function is discussed.     

Evidence for a ferryl Fea3 in oxygenated cytochrome c oxidase

Evidence is reported which shows that a reactive ferryl Fea3/cupric CuB binuclear couple is present at the dioxygen reduction site in "oxygenated" cytochrome c oxidase; when the fully reduced enzyme is reoxidized at low temperatures; and when partially reduced cytochrome c oxidase is reoxidized with dioxygen at room temperature.     

A re-examination of the reactions of cyanide with cytochrome c oxidase

Experiments were performed to examine the cyanide-binding properties of resting and pulsed cytochrome c oxidase in both their stable and transient turnover states. Inhibition of the oxidation of ferrocytochrome c was monitored as a function of cyanide concentration. Cyanide binding to partially reduced forms produced by mixing cytochrome c oxidase with sodium dithionite was also examined. A model is presented that accounts fully for cyanide inhibition of the enzyme, the essential feature of which is the rapid, tight, binding of cyanide to transient, partially reduced, forms of the enzyme populated during turnover. Computer fitting of the experimentally obtained data to the kinetic predictions given by this model indicate that the cyanide-sensitive form of the enzyme binds the ligand with combination constants in excess of 10(6) M-1 X s-1 and with KD values of 50 nM or less. Kinetic difference spectra indicate that cyanide binds to oxidized cytochrome a33+ and that this occurs rapidly only when cytochrome a and CuA are reduced.     

Appearance of the v(FeIV = O) vibration from a ferryl-oxo intermediate in the cytochrome oxidase/dioxygen reaction

Time-resolved resonance Raman spectra have been recorded during the reaction of fully reduced (a2+a3(2+)) cytochrome oxidase with dioxygen at room temperature. In the spectrum recorded at 800 microseconds subsequent to carbon monoxide photolysis, a mode is observed at 790 cm-1 that shifts to 755 cm-1 when the experiment is repeated with 18O2. The frequency of this vibration and the magnitude of the 18O2 isotopic frequency shift lead us to assign the 790-cm-1 mode to the FeIV = O stretching vibration of a ferryl-oxo cytochrome a3 intermediate that occurs in the reaction of fully reduced cytochrome oxidase with dioxygen. The appearance and vibrational frequency of this mode were not affected when D2O was used as a solvent. This result suggests that the ferryl-oxo intermediate is not hydrogen bonded. We have also recorded Raman spectra in the high-frequency (1000-1700 cm-1) region during the oxidase/O2 reaction that show that the oxidation of cytochrome a2+ is biphasic. The faster phase is complete within 100 microseconds and is followed by a plateau region in which no further oxidation of cytochrome a occurs. The plateau persists to approximately 500 microseconds and is followed by the second phase of oxidation. These results on the kinetics of the redox activity of cytochrome a are consistent with the branched pathway discussed by Hill et al. [Hill, B., Greenwood, C., & Nichols, P. (1986) Biochim. Biophys. Acta 853, 91-113] for the oxidation of reduced cytochrome oxidase by O2 at room temperature.     

Kinetics of reduction of cytochrome c oxidase by dithionite and the effect of hydrogen peroxide

The reduction of cytochrome c oxidase by dithionite was reinvestigated with a flow-flash technique and with varied enzyme preparations. Since cytochrome a3 may be defined as the heme in oxidase which can form a photolabile CO adduct in the reduced state, it is possible to follow the time course of cytochrome a3 reduction by monitoring the onset of photosensitivity. The onset of photosensitivity and the overall rate of heme reduction were compared for Yonetani and Hartzell-Beinert preparations of cytochrome c oxidase and for the enzyme isolated from blue marlin and hammerhead shark. For all of these preparations the faster phase of heme reduction, which is dithionite concentration-dependent, is almost completed when the fraction of photosensitive material is still small. We conclude that cytochrome a3 in the resting enzyme is consistently reduced by an intramolecular electron transfer mechanism. To determine if this is true also for the pulsed enzyme, we examined the time course of dithionite reduction of the peroxide complex of the pulsed enzyme. It has been previously shown that pulsed cytochrome c oxidase can interact with H2O2 and form a stable room temperature peroxide adduct (Bickar, D., Bonaventura, J., and Bonaventura, C. (1982) Biochemistry 21, 2661-2666). Rather complex kinetics of heme reduction are observed when dithionite is added to enzyme preparations that contain H2O2. The time courses observed provide unequivocal evidence that H2O2 can, under these conditions, be used by cytochrome c oxidase as an electron acceptor. Experiments carried out in the presence of CO show that a direct dithionite reduction of cytochrome a3 in the peroxide complex of the pulsed enzyme does not occur.     

Formation of the "peroxy" intermediate in cytochrome c oxidase is associated with internal proton/hydrogen transfer

When dioxygen is reduced to water by cytochrome c oxidase a sequence of oxygen intermediates are formed at the reaction site. One of these intermediates is called the "peroxy" (P) intermediate. It can be formed by reacting the two-electron reduced (mixed-valence) cytochrome c oxidase with dioxygen (called P(m)), but it is also formed transiently during the reaction of the fully reduced enzyme with oxygen (called P(r)). In recent years, evidence has accumulated to suggest that the O-O bond is cleaved in the P intermediate and that the heme a(3) iron is in the oxo-ferryl state. In this study, we have investigated the kinetic and thermodynamic parameters for formation of P(m) and P(r), respectively, in the Rhodobacter sphaeroides enzyme. The rate constants and activation energies for the formation of the P(r) and P(m) intermediates were 1.4 x 10(4) s(-1) ( approximately 20 kJ/mol) and 3 x 10(3) s(-1) ( approximately 24 kJ/mol), respectively. The formation rates of both P intermediates were independent of pH in the range 6.5-9, and there was no proton uptake from solution during P formation. Nevertheless, formation of both P(m) and P(r) were slowed by a factor of 1.4-1.9 in D(2)O, which suggests that transfer of an internal proton or hydrogen atom is involved in the rate-limiting step of P formation. We discuss the origin of the difference in the formation rates of the P(m) and P(r) intermediates, the formation mechanisms of P(m)/P(r), and the involvement of these intermediates in proton pumping.     

Ca2+-dependent and independent mitochondrial damage in HepG2 cells that overexpress CYP2E1

The effect of detergents on electron and proton transfer in bovine cytochrome c oxidase was studied using steady-state and transient-state methods. Cytochrome c oxidase in lauryl maltoside has high maximal turnover (TN(max)=400 s(-1)), whereas activity is low (TN(max)=10 s(-1)) in Triton X-100. Single turnover studies of intramolecular electron transfer show similar rates in either detergent. Transient proton uptake experiments show the oxidase in lauryl maltoside consumes 1.8+/-0.3 H(+)/aa(3) during either partial reduction of the oxidase or reaction of fully reduced enzyme with O(2). However, the oxidase in Triton X-100 consumes 2.6+/-0.4 H(+)/aa(3) during partial reduction and 1.0+/-0.2 H(+)/aa(3) in the O(2) reaction. Absorption spectra recorded during turnover show that the enzyme undergoes activation in lauryl maltoside, but does not activate in Triton X-100. We propose that cytochrome c oxidase in different detergents allows access to different sites of protonation, which in turn influences steady-state activity.     

The oxidation of cytochrome c oxidase by hydrogen peroxide

The reaction of H2O2 with mixed-valence and fully reduced cytochrome c oxidase was investigated by photolysis of fully reduced and mixed-valence carboxy-cytochrome c oxidase in the presence of H2O2 under anaerobic conditions. The results showed that H2O2 reacted rapidly (k = (2.5-3.1) X 10(4) M-1 X s-1) with both enzyme species. With the mixed-valence enzyme, the fully oxidised enzyme was reformed. On the time-scale of our experiments, no spectroscopically detectable intermediate was observed. This demonstrates that mixed-valence cytochrome c oxidase is able to use H2O2 as a two-electron acceptor, suggesting that cytochrome c oxidase may under suitable conditions act as a peroxidase. Upon reaction of H2O2 with the fully reduced enzyme, cytochrome a was oxidised before cytochrome a3. From this observation it was possible to estimate that the rate of electron transfer from cytochrome a to a3 is about 0.5-5 s-1.     

A homologous expression system for obtaining engineered cytochrome ba3 from Thermus thermophilus HB8

Cytochrome ba3 is an integral membrane protein that serves as a terminal oxidase of the respiratory chain in some prokaryotes. We have cloned the complete cba operon of Thermus thermophilus HB8 in an Escherichia coli/T. thermophilus shuttle vector. The ba3-encoding operon, cba, was eliminated from the chromosome of T. thermophilus strain MT111 using the pyrE system of Yamagishi and co-workers. Expression of functional cytochrome ba3 occurred in cells grown at reduced dioxygen levels. A hepta-histidine tag was placed at the N-terminus of subunit I, and a purification method for this form of the enzyme was developed. Growth conditions were investigated for moderate sized cultures (2L) with typical yields of approximately 2 mg of highly pure enzyme per liter of culture medium. The physical properties and enzymatic activities of these recombinant enzymes were compared with those of native enzyme. Recombinant enzyme lacking the histidine tag is spectrally identical to wild-type enzyme. Histidine-tagged cytochrome ba3 shows minor differences from wild-type, and it appears be somewhat less active as a cytochrome c552 oxidase. Exemplary mutants were also produced and compared to native protein. Tyrosine I-237, previously found to be covalently bonded to I-His-233, was changed to phenylalanine (I-Y237F) and to histidine (I-Y237H) in the hepta-histidine tagged cytochrome ba3. The Y to F mutant is devoid of enzyme activity whereas the Y to H mutant possesses approximately 5% wild-type oxidase activity; their properties are compared with those of wild-type enzyme. The above versions of the histidine-tagged enzyme have been crystallized, and our analysis of a 2.3 angstrom resolution electron-density map will be discussed elsewhere.     

Reaction of nitric oxide with the turnover intermediates of cytochrome c oxidase: reaction pathway and functional effects

The reactions of nitric oxide (NO) with the turnover intermediates of cytochrome c oxidase were investigated by combining amperometric and spectroscopic techniques. We show that the complex of nitrite with the oxidized enzyme (O) is obtained by reaction of both the "peroxy" (P) and "ferryl" (F) intermediates with stoichiometric NO, following a common reaction pathway consistent with P being an oxo-ferryl adduct. Similarly to chloride-free O, NO reacted with P and F more slowly [k approximately (2-8) x 10(4) M(-1) s(-1)] than with the reduced enzyme (k approximately 1 x 10(8) M(-1) s(-1)). Recovery of activity of the nitrite-inhibited oxidase, either during turnover or after a reduction-oxygenation cycle, was much more rapid than nitrite dissociation from the fully oxidized enzyme (t(1/2) approximately 80 min). The anaerobic reduction of nitrite-inhibited oxidase produced the fully reduced but uncomplexed enzyme, suggesting that reversal of inhibition occurs in turnover via nitrite dissociation from the cytochrome a(3)-Cu(B) site: this finding supports the hypothesis that oxidase may have a physiological role in the degradation of NO into nitrite. Kinetic simulations suggest that the probability for NO to be transformed into nitrite is greater at low electron flux through oxidase, while at high flux the fully reduced (photosensitive) NO-bound oxidase is formed; this is fully consistent with our recent finding that light releases the inhibition of oxidase by NO only at higher reductant pressure [Sarti, P., et al. (2000) Biochem. Biophys. Res. Commun. 274, 183].     

Reaction of dioxygen with cytochrome c oxidase reduced to different degrees: indications of a transient dioxygen complex with copper-B.

The reactions of the fully reduced, three-electron-reduced, and mixed-valence cytochrome oxidase with molecular oxygen have been followed in flow-flash experiments, starting from the CO complexes, at 445 and 830 nm at pH 7.4 and 25 degrees C. With the fully reduced and the three-electron-reduced enzyme, four kinetic phases with rate constants in the range from 1 x 10(5) to 10(3) s-1 can be observed. The initial fast phase is associated with an absorbance increase at 830 nm. This is followed by an absorbance decrease (2.8 x 10(4) s-1), the amplitude of which increases with the degree of reduction of the oxidase. The third phase (6 x 10(3) s-1) displays the largest absorbance change at both wavelengths in the fully reduced enzyme and is not seen in the mixed-valence oxidase at 830 nm; a change with opposite sign but with a similar rate constant is found at 445 nm in this enzyme form. The slowest phase (10(3) s-1) is also largest in the fully reduced oxidase and not seen in the mixed-valence enzyme. It is suggested that O2 initially binds to reduced CuB and is then transferred to cytochrome a3 before electron transfer from cytochrome a/CuA takes place. The fast oxidation of cytochrome a seen with the fully reduced enzyme is suggested not to occur during natural turnover. A reaction cycle for the complete turnover of the enzyme is presented. In this cycle, the oxidase oscillates between electron input and output states of the proton pump, characterized by cytochrome a having a high and a low reduction potential, respectively.     

Direct detection of a dioxygen adduct of cytochrome a3 in the mixed valence cytochrome oxidase/dioxygen reaction

Time-resolved resonance Raman spectra have been recorded during the reaction of mixed valence (a3+ a2+(3)) cytochrome oxidase with dioxygen at room temperature. In the spectrum recorded at 10 microseconds subsequent to carbon monoxide photolysis, a mode is observed at 572 cm-1 that shifts to 548 cm-1 when the experiment is repeated with 18O2. The appearance of this mode is dependent upon the laser intensity used and disappears at higher incident energies. The high frequency data in conjunction with the mid-frequency data allow us to assign the 572 cm-1 mode to the Fe-O stretching vibration of the low-spin O2 adduct that forms in the mixed valence cytochrome oxidase/dioxygen reaction. The 572 cm-1 v(Fe2(+)-O2) frequency in the mixed valence enzyme/O2 adduct is essentially identical to the 571 cm-1 frequency we measured for this mode during the reduction of O2 by the fully reduced enzyme (Varotsis, C., Woodruff, W. H., and Babcock, G. T. (1989) J. Am. Chem. Soc. 111, 6439-6440; Varotsis, C., Woodruff, W. H., and Babcock, G. T. (1990) J. Am. Chem. Soc. 112, 1297), which indicates that the O2-bound cytochrome a3 site is independent of the redox state of the cytochrome a/CuA pair. The photolabile oxy intermediate is replaced by photostable low- or intermediate-spin cytochrome a3+(3), with t1/2 congruent to 200 microseconds.     

Structures of reaction intermediates of bovine cytochrome c oxidase probed by time-resolved vibrational spectroscopy

Structures of reaction intermediates of bovine cytochrome c oxidase (CcO) in the reactions of its fully reduced form with O2 and fully oxidized form with H2O2 were investigated with time-resolved resonance Raman (RR) and infrared spectroscopy. Six oxygen-associated RR bands were observed for the reaction of CcO with O2. The isotope shifts for an asymmetrically labeled dioxygen, (16)O(18)O, has established that the primary intermediate of cytochrome a3 is an end-on type dioxygen adduct and the subsequent intermediate (P) is an oxoiron species with Fe=O stretch (nu(Fe=O)) at 804/764 cm(-1) for (16)O2/(18)O2 derivatives, although it had been long postulated to be a peroxy species. The P intermediate is converted to the F intermediate with nu(Fe=O) at 785/751 cm(-1) and then to a ferric hydroxy species with nu(Fe-OH) at 450/425 cm(-1) (443/417 cm(-1) in D2O). The rate of reaction from P to F intermediates is significantly slower in D2O than in H2O. The reaction of oxidized CcO with H2O2 yields the same oxygen isotope-sensitive bands as those of P and F, indicating the identity of intermediates. Time-resolved infrared spectroscopy revealed that deprotonation of carboxylic acid side chain takes place upon deligation of a ligand from heme a3. UV RR spectrum gave a prominent band due to cis C=C stretch of phospholipids tightly bound to purified CcO.     

Obligatory intermolecular electron-transfer from FAD to FMN in dimeric P450BM-3

Cytochromes P450 typically catalyze the monooxygenation of hydrophobic compounds resulting in the insertion of one atom of dioxygen into the organic substrate and the reduction of the other oxygen atom to water. The two electrons required for the reaction are normally provided by another redox active protein, for example cytochrome P450 reductase (CPR) in mammalian endoplasmic reticulum membranes. P450BM-3 from Bacillus megaterium is a widely studied P450 cytochrome in which the P450 is fused naturally to a diflavin reductase homologous to CPR. From the original characterization of the enzyme by Fulco's laboratory, the enzyme was shown to have a nonlinear dependence of reaction rate on enzyme concentration. In recent experiments we observed enzyme inactivation upon dilution, and the presence of substrate can diminish this inactivation. We therefore carried out enzyme kinetics, cross-linking experiments, and molecular weight determinations that establish that the enzyme is capable of dimerizing in solution. The dimer is the predominant form at higher concentrations under most conditions and is the only form with significant activity. Further experiments selectively knocking out the activity of individual domains with site-directed mutagenesis and measuring enzyme activity in heterologous dimers establish that the electron-transfer pathway in P450BM-3 passes through both protein molecules in the dimer during a single turnover, traversing from the FAD domain of one molecule into the FMN domain of the other molecule before passing to the heme domain. Analysis of our results combined with other analyses in the literature suggests that the heme domain of either monomer may accept electrons from the reduced FMN domain.