Elucidation of the mechanism of N-demethylation catalyzed by cytochrome P450 monooxygenase is facilitated by exploiting nitrogen-15 heavy isotope effects

¹⁵N heavy isotope effects are especially useful when detail is sought pertaining to the reaction mechanism for the cleavage of a C–N bond. Their potential in assisting to describe the mechanism of N-demethylation of tertiary amines by the action of cytochrome P450 monooxygenase has been investigated. As a working model for the first step, oxidation of the N-methyl group to N-methoxyl, tropine and a cytochrome P450 monooxygenase reaction centre composed of a truncated heme with sulfhydryl as the axial ligand were used. It is apparent that this first step of the reaction proceeds via a hydrogen atom transfer mechanism. Transition states for this step are described for both the high spin (⁴TS_H) and low spin (²TS_H) pathways in both gas and solvation states. Hence, overall normal secondary ¹⁵N KIE could be calculated for the reaction path modeled in the low spin state, and inverse for the reaction modeled in the high spin state. This partial reaction has been identified as the probable rate limiting step. The model for the second step, fission of the C–N bond, consisted of N-methoxylnortropine and two molecules of water. A transition state described for this step, TS_CN, gives a strongly inverse overall theoretical ¹⁵N KIE.     

Maturation of a eukaryotic cytochrome <Emphasis Type="Italic">c</Emphasis> in the cytoplasm of <Emphasis Type="Italic">Escherichia coli</Emphasis> without the assistance by a dedicated biogenesis apparatus

Maturation of c-type cytochromes involves the covalent and stereospecific enzymatic attachment of a heme b via thioether linkages to two conserved cysteines within apocytochromes. Horse cytochrome c is readily matured into its native holoform in the cytoplasm of E. coli when co-expressed with yeast cytochrome c heme lyase. Here we report the low yield formation of holocytochrome with covalently attached heme also in the absence of heme lyase. This is the first demonstration of in vivo maturation of a eukaryotic cytochrome c in a prokaryotic cytoplasm without the assistance by a dedicated enzymatic maturation system. The assembled cytochrome c can be oxidized by cytochrome c oxidase, indicating the formation of a functional protein. The absorption spectrum is typical of a low spin, six coordinated c-type heme. Nevertheless, minor spectral differences relative to the native cytochrome c, deviation of the midpoint reduction potential and slightly altered kinetic parameters of the interaction with cytochrome c oxidase emphasize the importance of cytochrome c heme lyase in folding cytochrome c into its native conformation.     

On the identity of the high spin heme components of cytochrome c oxidase

In oxidized, resting cytochrome c oxidase (EC 1.9.3.1) and under most conditions of partial reduction ? 50% of the heme components are detected by EPR spectroscopy. When the enzyme is fully reduced in the presence of equimolar quantities of cytochrome c, anaerobic reoxidation by an excess of a chemical oxidant (ferricyanide, porphyrexide) produces intense high and low spin heme signals simultaneously. The time range in which maximal high spin signals are observed is 0.1–2 s after mixing. Under these conditions 35–50% of the total heme a is accounted for by the low spin heme signal and 35–40% by the high spin signals, with the rhombic component accounting for 30–35% of the total heme. It is concluded that under these conditions, the major portion of both heme components must be EPR detectable. Thus, if the generally accepted assignment of the low spin signal to cytochrome a is adopted, it follows that in the experiments described, cytochrome a₃ is represented in the rhombic high spin signal. The quantities of heme represented in the axial high spin signal are too small for a definitive assignment; these signals could originate from either heme. When after formation of high spin signals as described, O₂ is admitted, the rhombic signal is eliminated within 4 ms. In the presence of the strongest rhombic high spin signals, the absorption band at 655 nm is only ? 25% developed. The implications of these findings are discussed in the context of present hypotheses concerning the state and interactions of cytochrome c oxidase components during oxidation-reduction.     

Single-crystal resonance Raman spectroscopy of site-directed mutants of cytochrome c peroxidase

Resonance Raman spectra are reported for single crystals of cytochrome c peroxidase (CCP) mutants, taken by using a microscope equipped with a variable-temperature stage. The spectra are similar to those observed for the mutant proteins in solution, but there are detectable differences having to do with the coordination and spin state of the heme. The Asn-235 mutant contains a mixture of six-coordinate high- and low-spin states with a detectably higher fraction of the former than in solution. Upon cooling even to 223 K, the heme is converted mostly to the low-spin form. The Phe-191 mutant likewise shows a high/low-spin six-coordinate mixture, together with a preponderant population of five-coordinate heme. Upon cooling, the high-spin six-coordinate population converts immediately to the low-spin form, while the five-coordinate population does so more slowly. This behavior is intermediate between that of native CCP and the Asn-235 mutant, consistent with an ancillary role for the normal Trp-191-Asp-235 H-bond in the proximal anchoring of the heme Fe. The Phe-51 mutant shows a dominant high-spin five-coordinate heme population in the single crystal, whereas in solution the six-coordinate form is dominant. This difference is mimicked by adding 2-methyl-2,4-pentanediol (MPD) to the solution and is attributed to the dehydrating effect of MPD, which is present during crystallization. Upon lowering the temperature, the five-coordinate heme converts partially to a six-coordinate high-spin form.(ABSTRACT TRUNCATED AT 250 WORDS)     

Resonance Raman and electron paramagnetic resonance structural investigations of neutrophil cytochrome b558.

The resonance Raman spectra of neutrophil cytochrome b558 obtained upon Soret excitation indicate that the heme is low spin six-coordinate in both ferric and ferrous oxidation states; comparison with the spectra of bis-imidazole hemin suggests imidazole or imidazolate axial ligation. Minor bands attributable to vibrational motions of ring-conjugated vinyl substituents were also observed, consistent with a heme assignment of protoporphyrin IX. The spectra of deoxycholate-solubilized cytochrome b558 were indistinguishable from neutrophil plasma membranes or specific granules, as were spectra from unstimulated and phorbol myristate acetate-stimulated cells, indicating that the hemes are structurally identical in various subcellular environments and cellular physiological states. However, structural complexity was suggested by biphasic ferric-ferrous photoreduction under 413-nm illumination and the absence of an EPR spectrum for the ferric heme under conditions where simple bis-imidazole heme-containing cytochromes are expected to give detectable signals. Midpoint reduction potentials and resonance Raman spectra of the soluble cytochrome b558 from an individual with cytochrome b558 positive (type IA.2) chronic granulomatous disease were nearly identical to normal oxidase, with the exception that the deficient oxidase did not undergo heme photoreduction. Possible structural models are discussed in relation to other physical properties (ligand binding, thermodynamic potentials) exhibited by the cytochrome.     

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

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

The pH dependence of the stereochemistry around the heme group in NO–cytochrome c (horse heart)

The electronic absorption, EPR and MCD spectra of NO derivatives of both ferrous and ferric cytochrome c (horse heart) have been measured in the pH region 2.0 to 12.9, in order to elucidate the pH dependence of the stereochemistry around the heme group. The reaction products of NO with ferrous cytochrome c in equilibrium were as follows: in the region 2.0 ⩽ pH ⩽ 5.3, NO–ferrous cytochrome c; in the region 5.3 < pH ⩽ 11.0, a mixture of NO–ferrous cytochrome c and native ferrous cytochrome c; at pH 12.0, NO–ferrous cytochrome c. At pH 2.0, the NO–ferrous cytochrome c contained a five-coordinate nitrosylheme as the major component and a six-coordinate species as the minor component, and at the order pH values it contained only the six-coordinate species. The reaction products of NO with ferric cytochrome c in equilibrium were as follows: in the region 2.0 ⩽ pH ⩽ 7.2, NO–ferric cytochrome c with six-coordinate nitrosylheme; in the region 7.2 < pH ⩽ 11.0, a mixture of NO–ferrous cytochrome c and native ferrous cytochrome c; at pH 12.0, NO–ferrous cytochrome c. Thus, the reaction of NO with ferric cytochrome c results in the formation of NO–ferrous cytochrome c, which is a typical case of reductive nitrosylation.     

A spin label study of lipid oxidation catalyzed by heme proteins

Rapid loss of the electron spin resonance signal from a variety of spin labels is observed when ferricytochrome c or metmyogloblin are combined with lipids. Evidence is presented that this loss of signal can be used as a sensitive method to study lipid oxidation catalyzed by heme proteins. Under aerobic conditions and with lipids which bind the heme protein, the kinetics of the oxidation process as observed by the spin label method are identical to the kinetics previously observed by measurements of oxygen uptake. Use of pre-oxidized lipids under anaerobic conditions indicates that cytochrome c reacts with a product of lipid oxidation. Kinetic studies of the anaerobic reaction indicate that cytochrome c reacts rapidly with lipid oxidation products in membrane areas far larger than the area occupied by cytochrome c, implying rapid transport of reactive species within the membrane interior in directions parallel to the membrane surface. Under anaerobic conditions, reaction of cytochrome c with lipid oxidation products appears to produce a relatively long lived (hours) species located in the hydrophobic portion of the membrane, which is capable of subsequent reaction with lipid-soluble spin labels.     

Identification of the proximal ligand His-20 in heme oxygenase (Hmu O) from Corynebacterium diphtheriae. Oxidative cleavage of the heme macrocycle does not require the proximal histidine

The coordination and spin-state of the Corynebacterium diphtheriae heme oxygenase (Hmu O) and the proximal Hmu O H20A mutant have been characterized by UV-visible and resonance Raman (RR) spectrophotometry. At neutral pH the ferric heme-Hmu O complex is a mixture of six-coordinate high spin and six-coordinate low spin species. Changes in the UV-visible and high frequency RR spectra are observed as a function of pH and temperature, with the six-coordinate high spin species being converted to six-coordinate low spin. The low frequency region of the ferrous RR spectrum identified the proximal ligand to the heme as a neutral imidazole with a Fe-His stretching mode at 222 cm(-1). The RR characterization of the heme-CO complex in wt-Hmu O confirms that the proximal imidazole is neither ionized or strongly hydrogen-bonded. Based on sequence identity with the mammalian enzymes the proximal ligand in HO-1 (His-25) and HO-2 (His-45) is conserved (His-20) in the bacterial enzyme. Site-specific mutagenesis identified His-20 as the proximal mutant based on electronic and resonance Raman spectrophotometric analysis. Titration of the heme-Hmu O complex with imidazole restored full catalytic activity to the enzyme, and the coordination of imidazole to the heme was confirmed by RR. However, in the absence of imidazole, the H20A Hmu O mutant was found to catalyze the initial alpha-meso-hydroxylation of the heme. The product of the aerobic reaction was determined to be ferrous verdoheme. Hydrolytic conversion of the verdoheme product to biliverdin concluded that oxidative cleavage of the porphyrin macrocycle was specific for the alpha-meso-carbon. The present data show that, in marked contrast to the human HO-1, the proximal ligand is not essential for the initial alpha-meso-hydroxylation of heme in the C. diphtheriae heme oxygenase-catalyzed reaction.     

The role of individual lysine residues of horse cytochrome <Emphasis Type="Italic">c</Emphasis> in the formation of reactive complexes with components of the respiratory chain

A number of mutant forms of horse cytochrome c with single or double substitutions of lysine residues near the heme cavity involved in interaction of mitochondrial cytochrome c with ubiquinol:cytochrome c reductase (EC 1.10.2.2) (complex III) and cytochrome c oxidase (EC 1.9.3.1) (complex IV) were prepared.. The succinate:cytochrome c reductase and cytochrome c oxidase activities of mitoplasts of rat liver were measured in the presence of mutant forms of cytochrome c. The lysine residues in positions 8, 27, 72, 86, and 87 were shown to be the main contribution to the formation of a reactive complex with ubiquinol:cytochrome c reductase of the respiratory chain, whereas the lysine residues in positions 13, 79, 86, and 87 were predominantly responsible for the formation of a complex with cytochrome c oxidase.     

Ascorbate peroxidase activity of cytochrome c

Abstract

The peroxidase-type reactivity of cytochrome c is proposed to play a role in free radical production and/or apoptosis. This study describes cytochrome c catalysis of peroxide consumption by ascorbate. Under conditions where the sixth coordination position at the cytochrome c heme iron becomes more accessible for exogenous ligands (by carboxymethylation, cardiolipin addition or by partial denaturation with guanidinium hydrochloride) this peroxidase activity is enhanced. A reaction intermediate is detected by stopped-flow UV-vis spectroscopy upon reaction of guanidine-treated cytochrome c with peroxide, which resembles the spectrum of globin Compound II species and is thus proposed to be a ferryl species. The ability of physiological levels of ascorbate (10–60 µM) to interact with this species may have implications for mechanisms of cell signalling or damage that are based on cytochrome c/peroxide interactions.     

Hyperfine correlation spectroscopy and electron spin echo envelope modulation spectroscopy study of the two coexisting forms of the hemeprotein cytochrome c6 from Anabaena Pcc7119

Oxidized cytochrome c₆ from Anabaena PCC 7119 was studied by electron spin echo envelope modulation spectroscopy. Hyperfine couplings of the unpaired electron with several nuclei were detected, in particular those of the nitrogens bound to the iron atom. Combining the experimental information here presented and previous continuous wave-electron paramagnetic resonance and electron nuclear double resonance results, some details on the electronic structure of the heme center in the protein are obtained. These results are discussed on the basis of a molecular model that considers one unpaired electron localized mainly in the iron d orbitals and propagation of the spin density within the heme center via spin polarization of the nitrogen σ-orbitals. The coexistence of two heme forms at physiological pH values in this c-type cytochrome is also discussed taking into account the experimental evidence.     

Evolutionary change of the heme c electronic structure: ferricytochrome c-551 from Pseudomonas aeruginosa and horse heart ferricytochrome c.

Individual assignments of the ¹H n.m.r. lines of heme c in reduced and oxidized cytochrome c-551 from $\text{Pseudomonas aeruginosa}$ were obtained by nuclear Overhauser enhancement and saturation transfer experiments. Comparison with the corresponding data on horse heart cytochrome c showed that the locations of high spin density on the heme c periphery as well as the in-plane principal axes x and y of the electronic g-tensor are rotated by approximately 90° in ferricytochrome c-551 relative to horse ferricytochrome c. High spin density in ferricytochrome c-551 is thus localized on the pyrrole ring III. While this pyrrole ring is well shielded in the interior of mammalian-type cytochromes c, it is more easily accessible in cytochrome c-551. It is suggested that this evolutionary change of the heme c electronic structure would be compatible with the hypothesis that the electron transfer in both species is via solvent exposed peripheral ring carbon atoms.     

Structure and spin density of ferric low-spin heme complexes determined with high-resolution ESEEM experiments at 35 GHz

The wide use of the heme group by nature is a consequence of its unusual “electronic flexibility.” Major changes in the electronic structure of this molecule can result from small perturbations in its environment. To understand the way the electronic distribution is dictated by the structure of the heme site, it is extremely important to have methods to reliably determine both of them. In this work we propose a way to obtain this information in ferric low-spin heme centers via the determination of g, A, and Q tensors of the coordinated nitrogens using electron spin echo envelope modulation experiments at Q-band microwave frequencies. The results for two bisimidazole heme model complexes, namely, PPIX(Im)₂ and CPIII(Im)₂, where PPIX is protoporphyrin IX, CPIII is coproporphyrin III, and Im is imidazole, selectively labeled with ¹⁵N on the heme or imidazole nitrogens are presented. The planes of the axial ligands were found to be parallel and oriented approximately along one of the N–Fe–N directions of the slightly ruffled porphyrin ring (approximately 10°). The spin density was determined to reside in an iron d orbital perpendicular to the heme plane and oriented along the other porphyrin N–Fe–N direction, perpendicular to the axial imidazoles. The benefit of the method presented here lies in the use of Q-band microwave frequencies, which improves the orientation selection, results in no/fewer combination lines in the spectra, and allows separation of the contributions of hyperfine and quadrupole interactions due to the fulfillment of the exact cancellation condition at g _Z and the possibility of performing hyperfine decoupling experiments at the g _X observer position. These experimental advantages make the interpretation of the spectra straightforward, which results in precise and reliable determination of the structure and spin distribution.     

Proton NMR study of the influence on iron oxidation/ligation/spin state on the heme orientational preference in myoglobin

Proton nuclear magnetic resonance spectroscopy has been utilized to demonstrate that the degree of heme orientational disorder within a given myoglobin protein matrix can be a sensitive function of the oxidation/ligation/spin state of the heme iron. For sperm whale deuterohemin-reconstituted myoglobin, the equilibrium was found to strongly favor (5.7 to 7.8 kJ/mol) the X-ray characterized heme orientation in all six-coordinate states, but with a considerable reduction in preference (to 1.6 kJ/mol) in the five-coordinate deoxy state. In native yellow fin tuna myoglobin, changes in heme orientational preferences of approximately 3 kJ/mol occur even between two six-coordinate ferric states differing solely in spin states.     

Spin-state equilibria and axial ligand bonding in FixL hydroxide: a resonance raman study

 Vibrational assignments for the Fe-OH unit of ferric alkaline forms of two deletion derivatives of Rhizobium meliloti FixL, FixL*, a functional O₂-sensing heme kinase, and FixLN, which contains only the heme domain, are made. Appearance of ²H- and ¹⁸O-sensitive Raman bands indicates that the heme group of FixL binds hydroxide as a distal ligand to form a six-coordinate complex. The alkaline FixLs are distributed between high- and low-spin states. The high- and low-spin bands corresponding to the ν (Fe-OH) modes occur at 479 and 539 cm^–1, respectively. Low temperature favors formation of the low-spin complex, indicative of a thermal spin-state equilibrium. The ν (Fe-OH) frequencies of FixLN and FixL* are 11 to 18 cm^–1 lower than those observed for the respective vibrations in alkaline myoglobin and hemoglobin. The weaker Fe-OH bond in the FixLs is attributed to a lack of hydrogen bonding on the distal side of the heme pocket. Received: 20 November 1997 / Accepted: 2 March 1998     

Comparison of Protein Structures in Solution Using Local Conformations Derived from NMR Data: Application to Cytochrome c

Abstract

Structural comparisons of proteins in solution are often required to examine structure-functional relationships, study structural effects of mutations or distinguish between various forms of the same molecule under different conditions. A nuclear magnetic resonance (NMR) based probabilistic strategy is presented and used to study the structural differences between the two redox states of cytochrome C in solution. A probabilistic approach is employed to calculate the main chain conformations of horse ferro- and ferricytochrome C in solution, based on the published sequential d connectivity data. Conformational differences between the two oxidation states of horse cytochrome C in solution are found to be statistically significant. The largest changes in conformation are at residues Lys27, Thr28, Leu32, Gln42, Thr47, Tyr48, Thr49, Glu69, Lys72, Met80, Phe82, Ile85 and Lys86, all of which are close to the heme (within 14 Å of the heme iron in the high resolution Xray structure of tuna cytochrome c). We suggest that these conformational changes may modulate local dipole moments and hence influence the interactions of cytochrome C with its physiological redox partners during the electron transfer process. The oxidation state dependent conformational differences are found to be much greater in solution than in the crystalline state, and the solution and crystal structures differ significantly in regions close to the heme. These results suggest that the highly charged nature of cytochrome C makes this protein particularly sensitive to the ionic strength of its environment and leads to differences between crystal and solution structures in the same oxidation state. In such cases, crystal structures must be used with caution for modeling molecular interactions in vivo. More generally, this analysis indicates that the determination of accurate local conformations based on nmr data can provide useful information about structure-functional aspects of proteins in solution.     

The biosynthesis of bacterial and plastidic c-type cytochromes

The biosynthesis of bacterial and plastidic c-type cytochromes includes several steps that occur post-translationally. In the case of bacterial cytochromes, the cytosolically synthesized pre-proteins are translocated across the cytoplasmic membrane, the pre-proteins are cleaved to their mature forms and heme is ligated to the processed apoprotein. Although heme attachment has not been studied extensively at the biochemical level, molecular genetic approaches suggest that the reaction generally occurs after translocation of the apoprotein to the periplasm. Recent studies with Bradyrhizobium japonicum and Rhodobacter capsulatus indicate that the process of heme attachment requires the function of a large number of genes. Mutation of these genes generates a pleiotropic deficiency in all c-type cytochromes, suggesting that the gene products participate in processes required for the biosynthesis of all c-type cytochromes. In eukaryotic cells, the biosynthesis of photosynthetic c-type cytochromes is somewhat more complex owing to the additional level of compartmentation. Nevertheless, the basic features of the pathway appear to be conserved. For instance, as is the case in bacteria, translocation and processing of the pre-proteins is not dependent on heme attachment. Genetic analysis suggests that the nuclear as well as the plastid genomes encode functions required for heme attachment, and that these genes function in the biosynthesis of the membrane-associated as well as the soluble c-type cytochrome of chloroplasts. A feature of cytochromes c biogenesis that appears to be conserved between chloroplasts and mitochondria is the sub-cellular location of the heme attachment reaction (p-side of the energy transducing membrane). Continued investigation of all three experimental systems (bacteria, chloroplasts, mitochondria) is likely to lead to a greater understanding of the biochemistry of cytochrome maturation as well as the more general problem of cofactor-protein association during the assembly of an energy transducing membrane.Abbreviations CCHL cytochrome c/heme lyase - CC₁HL cytochrome cl/heme lyase - cyt cytochrome - EMS ethyl methane sulphonate - n-side electrochemically negative side of an energy transducing membrane - p-side electrochemically positive side of an energy transducing membrane - PhoA alkaline phosphatase (encoded by the phoA locus)     

Axial coordination of ferric Aplysia myoglobin

Resonance Raman spectra of ferric Aplysia myoglobin in the ligand-free and the azide-bound forms have been studied over a wide pH range to determine the coordination states of the heme iron atom. In the hydroxide form at high pH (approximately 9) the iron is six-coordinate and is in a high/low spin equilibrium. As the pH is lowered below the acid/alkaline transition (pKa = 7.5), the heme becomes five-coordinate. When the pH is lowered even further no other changes in the resonance Raman spectrum are detected; thus, the heme remains five-coordinate down to pH 4, the lowest value studied. For ferric azide-bound Aplysia myoglobin, the iron is six-coordinate in a high/low spin equilibrium at all pH values (4.8-9). These data indicate (i) that the unusual reactivity toward azide previously observed at neutral pH is indeed related to the absence of a coordinated water molecule, and (ii) that causes other than the heme coordination are responsible for the spectral differences and the ligand-binding kinetics differences observed below pH 6.     

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).