Heme-heme communication during the alkaline-induced structural transition in cytochrome c oxidase

Alkaline-induced conformational changes at pH 12.0 in the oxidized as well as the reduced state of cytochrome c oxidase have been systematically studied with time-resolved optical absorption and resonance Raman spectroscopies. In the reduced state, the heme a(3) first converts from the native five-coordinate configuration to a six-coordinate bis-histidine intermediate as a result of the coordination of one of the Cu(B) ligands, H290 or H291, to the heme iron. The coordination state change in the heme a(3) causes the alteration in the microenvironment of the formyl group of the heme a(3) and the disruption of the H-bond between R38 and the formyl group of the heme a. This structural transition, which occurs within 1min following the initiation of the pH jump, is followed by a slower reaction, in which Schiff base linkages are formed between the formyl groups of the two hemes and their nearby amino acid residues, presumably R38 and R302 for the heme a and a(3), respectively. In the oxidized enzyme, a similar Schiff base modification on heme a and a(3) was observed but it is triggered by the coordination of the H290 or H291 to heme a(3) followed by the breakage of the native proximal H378-iron and H376-iron bonds in heme a and a(3), respectively. In both oxidation states, the synchronous formation of the Schiff base linkages in heme a and a(3) relies on the structural communication between the two hemes via the H-bonding network involving R438 and R439 and the propionate groups of the two hemes as well as the helix X housing the two proximal ligands, H378 and H376, of the hemes. The heme-heme communication mechanism revealed in this work may be important in controlling the coupling of the oxygen and redox chemistry in the heme sites to proton pumping during the enzymatic turnover of CcO.     

Resonance Raman evidence for an exchangeable protein hydrogen associated with the heme a group of cytochrome oxidase

When cytochrome-c oxidase is soaked in D2O, downshifts of the cytochrome a formyl C = O stretching mode are seen in the resonance Raman (RR) spectra (413.1 nm excitation) of both the resting and reduced forms. Other changes observed in the reduced protein RR spectra are consistent with involvement of the cytochrome a formyl group in the deuterium effect. The D2O-induced RR changes are fully developed during 3-5 days incubation, but are incomplete after 1 h. Extraction of the heme a chromophore in deuterated solvents eliminates these changes, implying that the exchangeable proton is on a protein group in the cytochrome a pocket which H-bonds to the heme formyl. The rate of the D2O exchange process is unaffected by enzyme turnover, thus reducing the likelihood that the cytochrome a formyl H-bond is directly involved in the redox-linked mechanism of proton pumping.     

Evaluating the roles of the heme a side chains in cytochrome c oxidase using designed heme proteins

Heme a is a redox cofactor unique to cytochrome c oxidases and vital to aerobic respiration. Heme a differs from the more common heme b by two chemical modifications, the C-8 formyl group and the C-2 hydroxyethylfarnesyl group. The effects of these porphyrin substituents on ferric and ferrous heme binding and electrochemistry were evaluated in a designed heme protein maquette. The maquette scaffold chosen, [Delta7-H3m](2), is a four-alpha-helix bundle that contains two bis(3-methyl-l-histidine) heme binding sites with known absolute ferric and ferrous heme b affinities. Hemes b, o, o+16, and heme a, those involved in the biosynthesis of heme a, were incorporated into the bis(3-methyl-l-histidine) heme binding sites in [Delta7-H3m](2). Spectroscopic analyses indicate that 2 equiv of each heme binds to [Delta7-H3m](2), as designed. Equilibrium binding studies of the hemes with the maquette demonstrate the tight affinity for hemes containing the C-2 hydroxyethylfarnesyl group in both the ferric and ferrous forms. Coupled with the measured equilibrium midpoint potentials, the data indicate that the hydroxyethylfarnesyl group stabilizes the binding of both ferrous and ferric heme by at least 6.3 kcal/mol via hydrophobic interactions. The data also demonstrate that the incorporation of the C-8 formyl substituent in heme a results in a 179 mV, or 4.1 kcal/mol, positive shift in the heme reduction potential relative to heme o due to the destabilization of ferric heme binding relative to ferrous heme binding. The two substituents appear to counterbalance each other to provide for tighter heme a affinity relative to heme b in both the ferrous and ferric forms by at least 6.3 and 2.1 kcal/mol, respectively. These results also provide a rationale for the reaction sequence observed in the biosynthesis of heme a.     

Mitochondrial ferredoxin is required for heme A synthesis in Saccharomyces cerevisiae.

Heme A is a prosthetic group of all eukaryotic and some prokaryotic cytochrome oxidases. This heme differs from heme B (protoheme) at two carbon positions of the porphyrin ring. The synthesis of heme A begins with farnesylation of the vinyl group at carbon C-2 of heme B. The heme O product of this reaction is then converted to heme A by a further oxidation of a methyl to a formyl group on C-8. In a previous study (Barros, M. H., Carlson, C. G., Glerum, D. M., and Tzagoloff, A. (2001) FEBS Lett. 492, 133-138) we proposed that the formyl group is formed by an initial hydroxylation of the C-8 methyl by a three-component monooxygenase consisting of Cox15p, ferredoxin, and ferredoxin reductase. In the present study three lines of evidence confirm a requirement of ferredoxin in heme A synthesis. 1) Temperature-conditional yah1 mutants grown under restrictive conditions display a decrease in heme A relative to heme B. 2) The incorporation of radioactive delta-aminolevulinic acid into heme A is reduced in yah1 ts but not in the wild type after the shift to the restrictive temperature; and 3) the overexpression of Cox15p in cytochrome oxidase mutants that accumulate heme O leads to an increased mitochondrial concentration of heme A. The increase in heme A is greater in mutants that overexpress Cox15p and ferredoxin. These results are consistent with a requirement of ferredoxin and indirectly of ferredoxin reductase in hydroxylation of heme O.     

Interaction between the formyl group of heme a and arginine 54 in cytochrome aa(3) from Paracoccus denitrificans

The optical spectrum of heme a is red-shifted in aa(3)-type cytochrome c oxidases compared to isolated low-spin heme A model compounds. Early spectroscopic studies indicated that this may be due to hydrogen-bonding of the formyl group of heme a to an amino acid in the close vicinity. Here we show that most of the optical spectral shift of native heme a is due to a hydrogen-bonding interaction between the formyl group and arginine-54 in subunit I of cytochrome aa(3) from Paracoccus denitrificans, and that a smaller part is due to an electrostatic interaction between the D ring propionate of heme a and arginine-474.     

Vibrational structure of the formyl group on heme a. Implications on the properties of cytochrome c oxidase.

Resonance Raman spectra have been recorded for heme a derivatives in which the oxygen atom of the formyl group has been isotopically labeled and for Schiff base derivatives of heme a in which the Schiff base nitrogen has been isotopically labeled. The 14N-15N isotope shift in the C = N stretching mode of the Schiff base is close to the theoretically predicted shift for an isolated C = N group for both the ferric and ferrous oxidation states and in both aqueous and nonaqueous solutions. In contrast, the 16O-18O isotope shift of the C = O stretching mode of the formyl group is significantly smaller than that predicted for an isolated C = O group and is also dependent on whether the environment is aqueous or nonaqueous. This differences between the theoretically predicted shifts and the observed shifts are attributed to coupling of the C = O stretching mode to as yet unidentified modes of the heme. The complex behavior of the C = O stretching vibration precludes the possibility of making simple interpretations of frequency shifts of this mode in cytochrome c oxidase.     

Formylation of tetrahydrofolate by formyl phosphate

Formyl phosphate is the putative intermediate in the formylation of tetrahydrofolate (THF) catalyzed by N10-formylTHF synthetase. In this study the non-enzymic reaction between formyl phosphate and THF was examined at 5 degrees C. 1H-NMR, HPLC and kinetic analysis of the proton-catalyzed conversion of the product to N5,10-methenylTHF were used to identify the product. In contrast to the enzyme reaction, which produces N10-formylTHF, N5-formylTHF was the only formylated THF derivative formed. The reaction was conducted at pH values of 3, 5, and 7, with the highest yield being obtained at pH 5 (64-85%, based on THF). The enzyme, therefore, changes the regioselectivity of this reaction by increasing the reactivity of the 10-nitrogen and either decreasing the reactivity of the 5-nitrogen or limiting its accessibility to formyl phosphate. 2-Mercaptoethanol, present in the reaction mixture to protect THF from O2, was also formylated by formyl phosphate, at the oxygen position.     

Heme A biosynthesis

Respiration in plants, most animals and many aerobic microbes is dependent on heme A. This is a highly specialized type of heme found as prosthetic group in cytochrome a-containing respiratory oxidases. Heme A differs structurally from heme B (protoheme IX) by the presence of a hydroxyethylfarnesyl group instead of a vinyl side group at the C2 position and a formyl group instead of a methyl side group at position C8 of the porphyrin macrocycle. Heme A synthase catalyzes the formation of the formyl side group and is a poorly understood heme-containing membrane bound atypical monooxygenase. This review presents our current understanding of heme A synthesis at the molecular level in mitochondria and aerobic bacteria. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

Heme A biosynthesis

Respiration in plants, most animals and many aerobic microbes is dependent on heme A. This is a highly specialized type of heme found as prosthetic group in cytochrome a-containing respiratory oxidases. Heme A differs structurally from heme B (protoheme IX) by the presence of a hydroxyethylfarnesyl group instead of a vinyl side group at the C2 position and a formyl group instead of a methyl side group at position C8 of the porphyrin macrocycle. Heme A synthase catalyzes the formation of the formyl side group and is a poorly understood heme-containing membrane bound atypical monooxygenase. This review presents our current understanding of heme A synthesis at the molecular level in mitochondria and aerobic bacteria. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

FTIR studies of internal proton transfer reactions linked to inter-heme electron transfer in bovine cytochrome c oxidase

FTIR difference spectroscopy is used to reveal changes in the internal structure and amino acid protonation states of bovine cytochrome c oxidase (CcO) that occur upon photolysis of the CO adduct of the two-electron reduced (mixed valence, MV) and four-electron reduced (fully reduced, FR) forms of the enzyme. FTIR difference spectra were obtained in D(2)O (pH 6-9.3) between the MV-CO adduct (heme a(3) and Cu(B) reduced; heme a and Cu(A) oxidized) and a photostationary state in which the MV-CO enzyme is photodissociated under constant illumination. In the photostationary state, part of the enzyme population has heme a(3) oxidized and heme a reduced. In MV-CO, the frequency of the stretch mode of CO bound to ferrous heme a(3) decreases from 1965.3 cm(-1) at pH* 相似文献   

Cytochrome c oxidase: evidence for interaction of water molecules with cytochrome a

The resonance Raman spectra of cytochrome c oxidase in protonated buffer compared to that in deuterated buffer indicate that water molecules are near the heme of cytochrome a. Differences in widths of the heme line at 1610 cm-1, after short exposure to D2O, and, additionally, of the heme line at 1625 cm-1, after long exposure, can be accounted for by changes in resonance vibrational energy transfer between modes of cytochrome a2+ and the bending mode of water molecules in the heme pocket. On the basis of the assignment of these modes, we place one water molecule near the vinyl group and one water molecule near the formyl group of the cytochrome a heme. These water molecules may play several possible functional roles.     

Heme A synthase enzyme functions dissected by mutagenesis of Bacillus subtilis CtaA

Heme A, as a prosthetic group, is found exclusively in respiratory oxidases of mitochondria and aerobic bacteria. Bacillus subtilis CtaA and other heme A synthases catalyze the conversion of a methyl side group on heme O into a formyl group. The catalytic mechanism of heme A synthase is not understood, and little is known about the composition and structure of the enzyme. In this work, we have: (i) constructed a ctaA deletion mutant and a system for overproduction of mutant variants of the CtaA protein in B. subtilis, (ii) developed anaffinity purification procedure for isolation of preparative amounts of CtaA, and (iii) investigated the functional roles of four invariant histidine residues in heme A synthase by in vivo and in vitro analyses of the properties of mutant variants of CtaA. Our results show an important function of three histidine residues for heme A synthase activity. Several of the purified mutant enzyme proteins contained tightly bound heme O. One variant also contained trapped hydroxylated heme O, which is a postulated enzyme reaction intermediate. The findings indicate functional roles for the invariant histidine residues and provide strong evidence that the heme A synthase enzyme reaction includes two consecutive monooxygenations.     

Optical and resonance Raman spectroscopy of the heme groups of the quinol-oxidizing cytochrome aa3 of Bacillus subtilis.

The cytochrome aa3-type terminal quinol oxidase of Bacillus subtilis catalyzes the four-electron reduction of dioxygen to water. It resembles the aa3-type cytochrome-c oxidase in using heme A as its active-site chromophores but lacks the CuA center and the cytochrome-c oxidizing activity of the mitochondrial enzyme. We have used optical and resonance Raman spectroscopies to study the B. subtilis oxidase in detail. The alpha-band absorption maximum of the reduced minus oxidized enzyme is shifted by 5-7 nm to the blue relative to most other aa3-type oxidases, and accordingly, we designate the Bacillus enzyme as cytochrome aa3-600. The shifted optical spectrum cannot be ascribed to an alteration in the strength of the hydrogen bond between the formyl group of the low-spin heme and its environment, as the Raman line assigned to this mode in aa3-600 has the same frequency and degree of resonance enhancement as the low-spin heme a formyl mode in most other aa3-type oxidases. Raman modes arise at 194 and 214 cm-1 in aa3-600, whereas a single band at about 214 cm-1 is assigned to the iron-histidine stretch for the other aa3-type oxidases. Possible explanations for the occurrence of these two modes are discussed. Comparison of formyl and vinyl modes and heme skeletal vibrational modes in different oxidation states of aa3-600 and of beef heart cytochrome-c oxidase shows a strong similarity, which suggests conservation of essential features of the heme environments in these oxidases.     

Measurement of the pH of frozen buffer solutions by using pH indicators.

A method was established to estimate the pH change of several buffers solutions on freezing by using a combination of pH indicators. Among more than 30 buffers solutions examined, almost half exhibited a pH change in the temperature range between freezing point and 220 degrees K; the results were tabulated. Glycerol was found to suppress the pH changes because of its "salt buffer" effect.     

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.     

The use of pH indicators to identify suitable environments for freezing samples in aqueous and mixed aqueous/nonaqueous solutions

The colours of frozen solutions containing pH indicators are shown to provide a test for changes in pH in the solvent environment which occur on freezing. Yeast alcohol dehydrogenase loses activity on freezing in phosphate buffer (a buffer in which pH indicator colour changes shows a marked decrease in pH on freezing) but when frozen in bis-tris, Hepes, or N-glycylglycine buffers (all of which show little change in the colour of universal pH indicator and hence of pH on freezing) is stable on freezing. The effects of freezing in different buffer systems on the rate of decomposition of NADPH, and on the rate hydrolysis of 4-nitrophenyl acetate, are rationalised in terms of the pH shifts in these buffers which were determined using universal pH indicator. It is proposed that a major reason for the instability of samples on freezing is the pH changes which occur when some systems are frozen. From the results a general scheme for selecting the best environment for safely freezing samples is proposed which is based on the use of pH indicators.     

Myeloperoxidase of the leukocyte of normal blood. Nature of the prosthetic group of myeloperoxidase

The absorption spectra of alkaline pyridine hemochrome of myeloperoxidase in its native, acid, and modified forms were similar to those of heme a, and the molar extinction coefficient of myeloperoxidase heme was very similar to that of heme a, assuming that myeloperoxidase contains only one heme. The anaerobic titration of myeloperoxidase with dithionite showed that one electron was consumed per molecule of the enzyme for its conversion to its reduced form. The EPR spectrum of myeloperoxidase indicated that the enzyme contains both high-spin heme and non-heme iron. Carbonyl reagents, such as borohydride, hydrazine, and benzhydrazide, reacted with myeloperoxidase, causing blue shifts in its absorption spectrum. The heme was labeled with a tritium of boro[3H]hydride, suggesting that the reagents reacted with a formyl group on the porphyrin ring of the myeloperoxidase heme. When hydrazine was added to cyanide complex I of myeloperoxidase the complex was converted to the hydrazine-enzyme compound. Myeloperoxidase reacted with bisulfite to form a compound with an absorption spectrum similar to that of cyanide complex I. Borohydride-treated myeloperoxidase formed only one cyanide complex, while the native enzyme formed two different cyanide complexes, I (Kd = 0.3 muM) and II (approximate Kd = 0.1 mM). The EPR spectrum indicated that cyanide complex I of myeloperoxidase still contained high-spin heme. The results suggested that cyanide complex I and the bisulfite compound of myeloperoxidase were adducts between the nucleophilic reagents and the formyl group of myeloperoxidase heme. Based on these results, we concluded that one of the two iron atoms in a myeloperoxidase molecule exists in a formyl-heme moiety similar to heme a and the other exists as a non-heme iron.     

Water-hydroxide exchange reactions at the catalytic site of heme-copper oxidases

Membrane-bound heme-copper oxidases catalyze the reduction of O(2) to water. Part of the free energy associated with this process is used to pump protons across the membrane. The O(2) reduction reaction results in formation of high-pK(a) protonatable groups at the catalytic site. The free energy associated with protonation of these groups is used for proton pumping. One of these protonatable groups is OH(-), coordinated to the heme and Cu(B) at the catalytic site. Here we present results from EPR experiments on the Rhodobacter sphaeroides cytochrome c oxidase, which show that at high pH (9) approximately 50% of oxidized heme a(3) is hydroxide-ligated, while at low pH (6.5), no hydroxide is bound to heme a(3). The kinetics of hydroxide binding to heme a(3) were investigated after dissociation of CO from heme a(3) in the enzyme in which the heme a(3)-Cu(B) center was reduced while the remaining redox sites were oxidized. The dissociation of CO results in a decrease of the midpoint potential of heme a(3), which results in electron transfer (tau approximately equal 3 micros) from heme a(3) to heme a in approximately 100% of the enzyme population. At pH >7.5, the electron transfer is followed by proton release from a H(2)O molecule to the bulk solution (tau approximately equal 2 ms at pH 9). This reaction is also associated with absorbance changes of heme a(3), which on the basis of the results from the EPR experiments are attributed to formation of hydroxide-ligated heme a(3). The OH(-) bound to heme a(3) under equilibrium conditions at high pH is also formed transiently after O(2) reduction at low pH. It is proposed that the free energy associated with electron transfer to the binuclear center and protonation of this OH(-) upon reduction of the recently oxidized enzyme provides the driving force for the pumping of one proton.     

Structural change and catalytic activity of horseradish peroxidase in oxidative polymerization of phenol

The effects of solvent and reaction conditions on the catalytic activity of horseradish peroxidase (HRP) were investigated for oxidative polymerization of phenol in water/organic mixtures using hydrogen peroxide as an oxidant. Also, the structural changes of HRP were investigated by CD and absorption spectroscopy in these solvents. The results suggest that the yield of phenol polymer (the conversion of phenol to polymer) is strongly affected by the reaction conditions due to the structural changes of HRP, that is, the changes in higher structure of the apo-protein and dissociation or decomposition of the prosthetic heme. Optimum solvent compositions for phenol polymerization depend on the nature of the organic solvents owing to different effects of the solvents on HRP structure. In addition to initial rapid changes, slower changes of HRP structure occur in water/organic solvents especially at high concentrations of organic solvents. In parallel with these structural changes, catalytic activity of HRP decreases with time in these solvents. At higher reaction temperatures, the yield of the polymer decreases, which is also ascribed to modification of HRP structure. It is known that hydrogen peroxide is an inhibitor of HRP, and the yield of phenol polymer is strongly dependent on the manner of addition of hydrogen peroxide to the reaction solutions. The polymer yield decreases significantly when hydrogen peroxide was added to the reaction solution in a large amount at once. This is probably due to inactivation of HRP by excess hydrogen peroxide. From the CD and absorption spectra, it is suggested that excess hydrogen peroxide causes not only decomposition of the prosthetic heme but also modification of the higher structure of HRP.     

Structural Change and Catalytic Activity of Horseradish Peroxidase in Oxidative Polymerization of Phenol

The effects of solvent and reaction conditions on the catalytic activity of horseradish peroxidase (HRP) were investigated for oxidative polymerization of phenol in water/organic mixtures using hydrogen peroxide as an oxidant. Also, the structural changes of HRP were investigated by CD and absorption spectroscopy in these solvents. The results suggest that the yield of phenol polymer (the conversion of phenol to polymer) is strongly affected by the reaction conditions due to the structural changes of HRP, that is, the changes in higher structure of the apo-protein and dissociation or decomposition of the prosthetic heme. Optimum solvent compositions for phenol polymerization depend on the nature of the organic solvents owing to different effects of the solvents on HRP structure. In addition to initial rapid changes, slower changes of HRP structure occur in water/organic solvents especially at high concentrations of organic solvents. In parallel with these structural changes, catalytic activity of HRP decreases with time in these solvents. At higher reaction temperatures, the yield of the polymer decreases, which is also ascribed to modification of HRP structure. It is known that hydrogen peroxide is an inhibitor of HRP, and the yield of phenol polymer is strongly dependent on the manner of addition of hydrogen peroxide to the reaction solutions. The polymer yield decreases significantly when hydrogen peroxide was added to the reaction solution in a large amount at once. This is probably due to inactivation of HRP by excess hydrogen peroxide. From the CD and absorption spectra, it is suggested that excess hydrogen peroxide causes not only decomposition of the prosthetic heme but also modification of the higher structure of HRP.