Electronic and stereochemical characterizations of intermediates in the photolysis of ferric cytochrome P450scc nitrosyl complexes. Effects of cholesterol and its analogues on ligand binding structures.

Low temperature photolysis of nitric oxide from the nitrosyl complexes of ferric cytochrome P450scc was examined by EPR spectroscopy to elucidate the stereochemical interaction between heme-bound ligand and side-chain of cholesterol or its hydroxylated analogues at the substrate-binding site. The photoproducts of the NO complexes trapped at 5 K exhibited new EPR absorptions providing information on the steric crowding of the distal heme moiety. Without substrate, the photoproduct exhibited a broad EPR absorption at g-8 due to magnetic dipole-dipole interaction between the photo-dissociated NO (S = 1/2) and the ferric iron (S = 5/2). This indicates that the photo-dissociated NO can move far away from the heme iron in the less restricted distal heme moiety of the substrate-free cytochrome P450scc. In the presence of substrates, such as cholesterol, 20(S)-hydroxycholesterol, 22(S)-hydroxycholesterol, 22(R)-hydroxycholesterol, and 25-hydroxycholesterol, the EPR spectra of the photoproducts exhibited many variations having broad g-8 absorptions and/or the widespread signals together with zero-field absorption. Among the steroid complexes used, 20(S)-hydroxycholesterol complex exhibited a conspicuously widespread EPR signal with a distinct zero-field absorption due to a spin-coupled interaction between the ferric iron (S = 5/2) and the photolyzed NO (S = 1/2). These results indicate that the 20(S)-hydroxycholesterol complex has restricted substrate-binding structure and that the hydroxylation of the cholesterol side-chain at the 22R position is necessary to proceed the side-chain cleavage reaction properly in cytochrome P450scc.     

EPR studies of the photodissociation reactions of cytochrome c oxidase-nitric oxide complexes

Three complexes of NO with cytochrome c oxidase are described which are all photodissociable at low temperatures as measured by EPR. The EPR parameters of the cytochrome a2+(3)-NO complex are the same both in the fully reduced enzyme and in the mixed-valence enzyme. The kinetics of photodissociation of cytochrome a2+(3)-NO and recombination of NO with cytochrome a2+(3) (in the 30-70 K region) revealed no differences in structure between cytochrome a2+(3) in the fully reduced and the mixed-valence states. The action spectrum of the photodissociation of cytochrome a2+(3)-NO as measured by EPR has maxima at 595, 560 and 430 nm, and corresponds to the absorbance spectrum of cytochrome a2+(3)-NO. Photodissociation of cytochrome a2+(3)-NO in the mixed-valence enzyme changes the EPR intensity at g 3.03, due to electron transfer from cytochrome a2+(3) to cytochrome a3+. The extent of electron transfer was found to be temperature dependent. This suggests that a conformational change is coupled to this electron transfer. The complex of NO with oxidized cytochrome c oxidase shows a photodissociation reaction and recombination of NO (in the 20-40 K region) which differ completely from those observed in cytochrome a2+(3)-NO. The observed recombination occurs at a temperature 15 K lower than that found for the cytochrome a2+(3)-NO complex. The action spectrum of the oxidized complex shows a novel spectrum with maxima at 640 and below 400 nm; it is assigned to a Cu2+B-NO compound. The triplet species with delta ms = 2 EPR signals at g 4 and delta ms = 1 signals at g 2.69 and 1.67, that is observed in partially reduced cytochrome c oxidase treated with azide and NO, can also be photodissociated.     

Modifications in heme iron of free and vesicle bound cytochrome c by tert-butyl hydroperoxide: a magnetic circular dichroism and electron paramagnetic resonance investigation

To characterize changes to the heme and the influence of membrane lipids in the reaction of cytochrome c with peroxides, we studied the reaction of cytochrome c with tert-butyl hydroperoxide (tert-BuOOH) by magnetic circular dichroism (MCD) and direct electron paramagnetic resonance (EPR) in the presence and absence of different liposomes. Direct low-temperature (11 degrees K) EPR analysis of the cytochrome c heme iron on exposure to tert-BuOOH shows a gradual (180 s) conversion of the low-spin form to a high-spin Fe(III) species of rhombic symmetry (g = 4.3), with disappearance of a prior peroxyl radical signal (g(o) = 2.014). The conversion to high spin precedes Soret band bleaching, observable by UV/Vis spectroscopy and by magnetic circular dichroism (MCD) at room temperature, that indicates loss of iron coordination by the porphyrin ring. The presence of cardiolipin-containing liposomes delayed formation of the peroxyl radical and conversion to high-spin iron, while dicetylphosphate (DCP) liposomes accelerated these changes. Correspondingly, bleaching of cytochrome c by tert-BuOOH at room temperature was accelerated by several negatively charged liposome preparations, and inhibited by mitochondrial-mimetic phosphatidylcholinephosphatidylethanolaminecardiolipin (PCPECL) liposomes. Concomitant with bleaching, spin-trapping measurements with 5,5-dimethyl-1-pyroline-N-oxide showed that while the relative production of peroxyl, alkoxyl, and alkyl radicals was unaffected by DCP liposomes, PCPECL liposomes decreased the spin-trapped alkoxyl radical signal by 50%. The EPR results show that the primary initial change on exposure of cytochrome c to tert-BuOOH is a change to a high-spin Fe(III) species, and together with MCD measurements show that unsaturated cardiolipin-containing lipid membranes influence the interaction of tert-BuOOH with cytochrome c heme iron, to alter radical production and decrease damage to the cytochrome.     

Rapid intrachain binding of histidine-26 and histidine-33 to heme in unfolded ferrocytochrome C.

Time-resolved spectroscopic studies of unfolded horse iron(II) cytochrome c have suggested that the imidazole side chains of His26 and His33 bind transiently to the heme iron on microsecond time scales, after photodissociation of a carbon monoxide ligand from the heme. Our studies of four variants of cytochrome c (horse wild type, horse H33N, horse H33N/H26Q, and tuna wild type), unfolded in guanidine hydrochloride at pH 6.5, demonstrate that these side chains are responsible for the observed microsecond spectral changes. As His33 and then His26 are eliminated from the horse wild-type sequence, transient optical absorption spectra show systematic suppression of a rapid (approximately 10-100 micros) Soret absorbance change that follows photolysis of CO. Transient binding of these histidine side chains to the heme therefore generates one of the fast kinetic phases observed in previous photochemically triggered spectroscopic studies of dynamics in unfolded iron(II) cytochrome c. Furthermore, both His33 and His26 appear to contribute to a similar extent in these early kinetics. Thus, the stiffness of the polypeptide chain creates a deviation from Gaussian chain behavior by impeding, although not preventing, the formation of short (<10 peptide bonds) intrachain loops around the heme group.     

Molecular basis for nitric oxide dynamics and affinity with Alcaligenes xylosoxidans cytochrome c

The bacterial heme protein cytochrome ? from Alcaligenes xylosoxidans (AXCP) reacts with nitric oxide (NO) to form a 5-coordinate ferrous nitrosyl heme complex. The crystal structure of ferrous nitrosyl AXCP has previously revealed that NO is bound in an unprecedented manner on the proximal side of the heme. To understand how the protein structure of AXCP controls NO dynamics, we performed absorption and Raman time-resolved studies at the heme level as well as a molecular computational dynamics study at the entire protein structure level. We found that after NO dissociation from the heme iron, the structure of the proximal heme pocket of AXCP confines NO close to the iron so that an ultrafast (7 ps) and complete (99 +/- 1%) geminate rebinding occurs, whereas the proximal histidine does not rebind to the heme iron on the timescale of NO geminate rebinding. The distal side controls the initial NO binding, whereas the proximal heme pocket controls its release. These dynamic properties allow the trapping of NO within the protein core and represent an extreme behavior observed among heme proteins.     

The cytochrome c oxidase-azide-nitric oxide complex as a model for the oxygen-binding site

The complex of cytochrome c oxidase with NO and azide has been studied by EPR at 9.2 and 35 GHz. This complex which shows delta ms = 2 EPR triplet and strong anisotropic signals, due to the interaction of cytochrome a2+3 X NO (S = 1/2) and Cu2+B (S = 1/2), is photodissociable . Its action spectrum is similar to that of cytochrome a2+3 X NO with bands at 430, 560 and 595 nm, but shows an additional band in the near ultraviolet region. The quantum yield of the photodissociation process of cytochrome a2+3 X NO in the metal pair appears to depend on the redox state of CuB. When the photolysed sample was warmed to 77 K, a complex was observed with the EPR parameters of cytochrome a3+3 - N-3 - Cu1 +B (S = 1/2). This process of electron and ligand transfer can be reversed by heating the sample to 220 K. It is suggested that in the triplet species azide is bound to Cu2+B whereas NO is bridged between Cu2+B and the haem iron of the cytochrome a2+3. The complex has a triplet ground state and a singlet excited state with an exchange interaction J = -7.1 cm-1 between both spins. The anisotropy in the EPR spectra is mainly due to a magnetic dipole-dipole interaction between cytochrome a2+3 X NO and Cu2+B. From simulations of the triplet EPR spectra obtained at 9 and 35 GHz, a value for the distance between the nitroxide radical and Cu2+B of 0.33 nm was found. A model of the NO binding in the cytochrome a3-Cu pair shows a distance between the haem iron of cytochrome a3 and CuB of 0.45 nm. It is concluded that the cytochrome a3-CuB pair forms a cage in which the dioxygen molecule is bidentate coordinated to the two metals during the catalytic reaction.     

Photodissociated cytochrome c oxidase: cryotrapped metastable intermediates

By freezing CO-bound cytochrome c oxidase at cryogenic temperatures, we have been able to cryotrap metastable intermediates of photodissociation. The differences in the resonance Raman spectrum between these intermediates and ligand-free reduced cytochrome oxidase at cryogenic temperatures are the same as those between the phototransient and the fully reduced preparation detected with 10-ns excitation at room temperature. The largest difference occurs in the iron-histidine stretching mode of cytochrome a3, which shifts by up to 8 cm-1 to higher frequency in the photoproduct. At 4 K the iron-histidine mode displays two unrelaxed frequencies in the photoproduct, which we attribute to two different unrelaxed structures of the heme pocket. The frequencies and intensities of the lines in the resonance Raman spectrum are sensitive to the incident laser power density in both the ligand-free fully reduced preparation and the photoproduct even at 4 K. At 77 K the carbonyl stretching mode of the formyl group in cytochrome a32+ is especially sensitive to laser power, displaying two frequencies-1666 cm-1 at low-flux density and 1674 cm-1 at high-flux density. These frequencies may reflect a change in conformation of the formyl group or a change in its interaction with the protein such as in hydrogen bonding to the carbonyl of the formyl group. The absence of immediate relaxation of the CO photoproduct must be considered when one studies the structure and kinetics of the O2 intermediates that are formed in triple trapping and flow-flash experiments following photodissociation of the CO-bound enzyme.     

Interaction of cytochrome bd with carbon monoxide at low and room temperatures: evidence that only a small fraction of heme b595 reacts with CO

Azotobacter vinelandii is an obligately aerobic bacterium in which aerotolerant dinitrogen fixation requires cytochrome bd. This oxidase comprises two polypeptide subunits and three hemes, but no copper, and has been studied extensively. However, there remain apparently conflicting reports on the reactivity of the high spin heme b(595) with ligands. Using purified cytochrome bd, we show that absorption changes induced by CO photodissociation from the fully reduced cytochrome bd at low temperatures demonstrate binding of the ligand with heme b(595). However, the magnitude of these changes corresponds to the reaction with CO of only about 5% of the heme. CO binding with a minor fraction of heme b(595) is also revealed at room temperature by time-resolved studies of CO recombination. The data resolve the apparent discrepancies between conclusions drawn from room and low temperature spectroscopic studies of the CO reaction with cytochrome bd. The results are consistent with the proposal that hemes b(595) and d form a diheme oxygen-reducing center with a binding capacity for a single exogenous ligand molecule that partitions between the hemes d and b(595) in accordance with their intrinsic affinities for the ligand. In this model, the affinity of heme b(595) for CO is about 20-fold lower than that of heme d.     

Nitric oxide reacts with the single-electron reduced active site of cytochrome c oxidase

The reduction kinetics of the mutants K354M and D124N of the Paracoccus denitrificans cytochrome oxidase (heme aa(3)) by ruthenium hexamine was investigated by stopped-flow spectrophotometry in the absence/presence of NO. Quick heme a reduction precedes the biphasic heme a(3) reduction, which is extremely slow in the K354M mutant (k(1) = 0.09 +/- 0.01 s(-1); k(2) = 0.005 +/- 0.001 s(-1)) but much faster in the D124N aa(3) (k(1) = 21 +/- 6 s(-1); k(2) = 2.2 +/- 0.5 s(-1)). NO causes a very large increase (>100-fold) in the rate constant of heme a(3) reduction in the K354M mutant but only a approximately 5-fold increase in the D124N mutant. The K354M enzyme reacts rapidly with O(2) when fully reduced but is essentially inactive in turnover; thus, it was proposed that impaired reduction of the active site is the cause of activity loss. Since at saturating [NO], heme a(3) reduction is approximately 100-fold faster than the extremely low turnover rate, we conclude that, contrary to O(2), NO can react not only with the two-electron but also with the single-electron reduced active site. This mechanism would account for the efficient inhibition of cytochrome oxidase activity by NO in the wild-type enzyme, both from P. denitrificans and from beef heart. Results also suggest that the H(+)-conducting K pathway, but not the D pathway, controls the kinetics of the single-electron reduction of the active site.     

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).     

M?ssbauer study of beef heart cytochrome oxidase. Comparative study of the bovine enzyme and cytochrome c1aa3 from Thermus thermophilus

We have studied beef heart cytochrome c oxidase at 4.2 K with M?ssbauer spectroscopy using the 57Fe present in natural abundance. The spectra observed are very similar to those of the a- and a3-sites of cytochrome c1aa3 from Thermus thermophilus. Thus, many conclusions derived from studies of the bacterial oxidase (available with enriched 57Fe) also apply to the mammalian enzyme. In the resting (as isolated) state, cytochrome a3 of the mammalian enzyme exhibits a doublet with quadrupole splitting, delta EQ = 1.0 mm/s and isomer shift, delta = 0.48 mm/s. These parameters suggest a high spin ferric heme and rule out an Fe(IV) assignment. The absence of magnetic features in the 4.2 K spectrum is consistent with earlier proposals that cytochrome a3 is spin-coupled to a cupric ion. The absorption lines are rather broad, suggesting that the a3-site is heterogeneous in the resting enzyme. Reduced cytochrome a3 has delta EQ = 1.85 mm/s and delta = 0.93 mm/s, demonstrating that the heme iron is high spin ferrous. The observed value for delta EQ is smaller than those of hemoglobin (2.4 mm/s), myoglobin (2.2 mm/s), and cytochrome a3 from T. thermophilus (2.06 mm/s). The M?ssbauer spectra of oxidized cytochrome a3-CN show that the heme iron is low spin ferric and that the ground state has integer spin S greater than or equal to 1, which plausibly results from ferromagnetic coupling of the S = 1/2 heme to an S = 1/2 cupric ion. Reduced cytochrome a is low spin ferrous, with parameters similar to those of cytochrome b5 and cytochrome c.     

Correlations between structural and spectroscopic properties of the high-spin heme protein cytochrome c'

The cytochromes c' are a class of heme proteins whose native spectroscopic properties have been suggested to represent a quantum mechanical admixture of intermediate-(S = 3/2) and high-(S = 5/2) spin states. Here features of the cytochrome c' heme environment, as revealed by X-ray crystallographic studies of the dimeric cytochrome c' from Rhodospirillum molischianum, are related to the observed spectroscopic properties. The environment of the heme group in cytochrome c' supports the existence of the admixed spin state at neutral pH and suggests that pH-dependent transition to a pure high-spin state at alkaline pH involves deprotonation of the histidine axial ligand to the heme iron.     

Electron paramagnetic resonance- (EPR-) resolved kinetics of cryogenic nitric oxide recombination to cytochrome c oxidase and myoglobin.

By the electron paramagnetic resonance (EPR) technique, recovery kinetics for nitric oxide (NO) to heme following cryogenic photolysis were studied for the nitrosylferrocytochrome a3 center in cytochrome c oxidase and for myoglobin. The recovery was nonexponential, as has been observed in previous cryogenic CO and O2 rebinding to heme systems. NO rebinding to heme a3 started near a temperature of 50 K and was related to a distribution of thermal activation energies. At the peak of the distribution the activation energy was 3.1 kcal/mol, and the preexponential in the recovery rate was 10(9.9) s-1. For recovery of NO back to the a3 heme, the activation energy was threefold less than that for CO where CO binds to nearby Cua3 following photolysis from heme a3, but was larger than the activation energy for CO, O2, and probably NO rebinding to myoglobin. NO ligand rebinding to myoglobin occurred at a temperature as low as 15 K and in a temperature regime where tunneling could occur. However, the rate of NO rebinding to myoglobin did increase with temperature in the 15-25 K range.     

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.     

EPR studies on the photo-induced intermediates of ferric NO complexes of rat neuronal nitric oxide synthase trapped at low temperature.

Rat neuronal nitric oxide synthase (nNOS) was expressed in Escherichia coli and purified. Although the nitric oxide (NO) complex of the ferric heme was EPR-silent, photo-illumination at 5 K to the NO complex of the ferric nNOS in the substrate-free form produced a new high spin EPR signal similar to that of the ferric heme of N(omega)-nitro-L-arginine-bound nNOS, suggesting that the photo-dissociated NO might move away from the heme. Low photo-dissociability of NO in this complex indicated less restricted movement of the dissociated NO in the distal region of the heme, which might result in the rapid rebinding of the NO to the ferric heme at 5 K. In the presence of substrate L-arginine, derivatives, or product L-citrulline, the photo-products from the ferric NO complexes exhibited large novel EPR signals with a spin-coupled interaction between the ferric heme (S = 5/2) and the photolyzed NO (S = 1/2), suggesting a stereochemically restricted interaction between the photo-dissociated NO and the guanidino- or the ureido-group of the substrate analogues at the distal heme region of nNOS. The photo-product from the NO complex produced from citrulline-bound nNOS might be the same intermediate species as that formed in the last step of the catalytic cycle.     

Purification and characterization of the MQH2:NO oxidoreductase from the hyperthermophilic archaeon Pyrobaculum aerophilum

The membrane-bound NO reductase from the hyperthermophilic denitrifying archaeon Pyrobaculum aerophilum was purified to homogeneity. The enzyme displays MQH2:NO oxidoreductase (qNOR) activity, consists of a single subunit, and contains heme and nonheme iron in a 2:1 ratio. The combined results of EPR, resonance Raman, and UV-visible spectroscopy show that one of the hemes is bis-His-coordinated low spin (gz = 3.015; gy = 2.226; gx = 1.45), whereas the other heme adopts a high spin configuration. The enzyme also contains one nonheme iron center, which in the oxidized enzyme is antiferromagnetically coupled to the high spin heme. This binuclear high spin heme/nonheme iron center is EPR-silent and the site of NO reduction. The reduced high spin heme is bound to a neutral histidine and can bind CO to form of a low spin complex. The oxidized high spin heme binds NO, yielding a ferric nitrosyl complex, the intermediate causing the commonly found substrate inhibition in NO reductases (Ki(NO) = 7 microm). The qNOR as present in the membrane is, in contrast to the purified enzyme, quite thermostable, incubation at 100 degrees C for 86 min leading to 50% inhibition. The pure enzyme lacks heme b and instead contains stoichiometric amounts of hemes Op1 and Op2, ethenylgeranylgeranyl and hydroxyethylgeranylgeranyl derivatives of heme b, respectively. The archaeal qNOR is the first example of a NO reductase, which contains modified hemes reminiscent of cytochrome bo3 and aa3 oxidases. This report is the first describing the purification and structural and spectroscopic properties of a thermostable NO reductase.     

Six- to five-coordinate heme-nitrosyl conversion in cytochrome c' and its relevance to guanylate cyclase

The 5-coordinate ferrous heme of Alcaligenes xylosoxidans cytochrome c' reacts with NO to form a 6-coordinate nitrosyl intermediate (lambdaSoret at 415 nm) which subsequently converts to a 5-coordinate nitrosyl end product (lambdaSoret at 395 nm) in a rate-determining step. Stopped-flow measurements at pH 8.9, 25 degrees C, yield a rate constant for the formation of the 6-coordinate nitrosyl adduct, k(on) = (4.4 +/- 0.5) x 10(4) M(-1) x s(-1), which is 3-4 orders of magnitude lower than the values for other pentacoordinate ferrous hemes and is consistent with NO binding within the sterically crowded distal heme pocket. Resonance Raman measurements of the freeze-trapped 6-coordinate nitrosyl intermediate reveal an unusually high Fe-NO stretching frequency of 579 cm(-1), suggesting a distorted Fe-N-O coordination geometry. The rate of 6- to 5-coordinate heme nitrosyl conversion is also dependent upon NO concentration, with a rate constant, k(6-5) = (8.1 +/- 0.7) x 10(3) M(-1) x s(-1), implying that an additional molecule of NO is required to form the 5c-NO adduct. Since crystallographic studies have shown that the 5-coordinate nitrosyl complex of cytochrome c' binds NO to the proximal (rather than distal) face of the heme, the NO dependence of the 6- to 5-coordinate NO conversion supports a mechanism in which the weakened His ligand, as well as the distally bound NO, is displaced by a second NO molecule which attacks and is retained in the proximal coordination position. The fact that a dependent 6- to 5-coordinate nitrosyl conversion has been previously reported for soluble guanylate cyclase suggests that the mechanism of Fe-His bond cleavage may be similar to that of cytochrome c' and strengthens the recent proposal that both proteins exhibit proximal NO binding in their 5-coordinate nitrosyl adducts.     

Heme protein dynamics revealed by geminate nitric oxide recombination in mutants of iron and cobalt myoglobin

Nitric oxide myoglobin (MbNO) at 300 K was photodissociated with 405 nm pulses. The NO recombination in several mutants of iron and cobalt myoglobins was investigated at a time resolution of ca. 70 fs. The geminate recombination of NO was nonexponential on sub-nanosecond time scales. For both metals, the change of the detailed structure of the heme pocket (position 68 mutations) caused significant changes in the rates of recombination; however, the metal substitution influenced the recombination much less than did amino acid substitution. The results indicate a primary role of the heme pocket structure in the dynamics, and they suggest that proximal protein relaxation is not the limiting factor in the geminate recombination process. Recombination in cobalt derivatives is somewhat more efficient on the sub-nanosecond time scales than in corresponding iron myoglobins, consistent with other results that show a greater intrinsic reactivity toward the NO of cobalt compared with the iron heme. A comparison of results using Soret band excitation with previous Q-state excitation studies demonstrates that the ligand dissociates with a similar kinetic energy in both cases, suggesting fast intramolecular energy redistribution before dissociation.     

EPR studies of the photodissociation reactions of cytochrome c oxidase-nitric oxide complexes

Three complexes of NO with cytochrome c oxidase are described which are all photodissociable at low temperatures as measured by EPR. The EPR parameters of the cytochrome a²⁺₃-NO complex are the same both in the fully reduced enzyme and in the mixed-valence enzyme. The kinetics of photodissociation of cytochrome a²⁺₃-NO and recombination of NO with cytochrome a²⁺₃ (in the 30–70 K region) revealed no differences in structure between cytochrome a²⁺₃ in the fully reduced and the mixed-valence states. The action spectrum of the photodissociation of cytochrome a²⁺₃-NO as measured by EPR has maxima at 595, 560 and 430 nm, and corresponds to the absorbance spectrum of cytochrome a²⁺₃-NO. Photodissociation of cytochrome a²⁺₃-NO in the mixed-valence enzyme changes the EPR intensity at g 3.03, due to electron transfer from cytochrome a²⁺₃ to cytochrome a³⁺. The extent of electron transfer was found to be temperature dependent. This suggests that a conformational change is coupled to this electron transfer. The complex of NO with oxidized cytochrome c oxidase shows a photodissociation reaction and recombination of NO (in the 20–40 K region) which differ completely from those observed in cytochrome a²⁺₃-NO. The observed recombination occurs at a temperature 15 K lower than that found for the cytochrome a²⁺₃-NO complex. The action spectrum of the oxidized complex shows a novel spectrum with maxima at 640 and below 400 nm; it is assigned to a Cu²⁺_B-NO compound. The triplet species with Δm_s = 2 EPR signals at g 4 and Δm_s = 1 signals at g 2.69 and 1.67, that is observed in partially reduced cytochrome c oxidase treated with azide and NO, can also be photodissociated.     

Electron paramagnetic resonance studies of Pseudomonas cytochrome c peroxidase

The EPR spectrum at 15 K of Pseudomonas cytochrome c peroxidase, which contains two hemes per molecule, is in the totally ferric form characteristic of low-spin heme giving two sets of g-values with gz 3.26 and 2.94. These values indicate an imidazole-nitrogen : heme-iron : methionine-sulfur and an imidazole-nitrogen : heme-iron : imidazole-nitrogen hemochrome structure, respectively. The spectrum is essentially identical at pH 6.0 and 4.6 and shows only a very small amount of high-spin heme iron (g 5--6) also at 77 K. Interaction between the two hemes is shown to exist by experiments in which one heme is reduced. This induces a change of the EPR signal of the other (to gz 2.83, gy 2.35 and gx 1.54), indicative of the removal of a histidine proton from that heme, which is axially coordinated to two histidine residues. If hydrogen peroxide is added to the partially reduced protein, its EPR signal is replaced by still other signals (gz 3.5 and 3.15). Only a very small free radical peak could be observed consistent with earlier mechanistic proposals. Contrary to the EPR spectra recorded at low temperature, the optical absorption spectra of both totally oxidized and partially reduced enzyme reveal the presence of high-spin heme at room temperature. It seems that a transition of one of the heme c moieties from an essentially high-spin to a low-spin form takes place on cooling the enzyme from 298 to 15 K.