Functional characterization of human duodenal cytochrome b (Cybrd1): Redox properties in relation to iron and ascorbate metabolism

Duodenal cytochrome b (Dcytb or Cybrd1) is an iron-regulated protein, highly expressed in the duodenal brush border membrane. It has ferric reductase activity and is believed to play a physiological role in dietary iron absorption. Its sequence identifies it as a member of the cytochrome b₅₆₁ family. A His-tagged construct of human Dcytb was expressed in insect Sf9 cells and purified. Yields of protein were increased by supplementation of the cells with 5-aminolevulinic acid to stimulate heme biosynthesis. Quantitative analysis of the recombinant Dcytb indicated two heme groups per monomer. Site-directed mutagenesis of any of the four conserved histidine residues (His 50, 86, 120 and 159) to alanine resulted in much diminished levels of heme in the purified Dcytb, while mutation of the non-conserved histidine 33 had no effect on the heme content. This indicates that those conserved histidines are heme ligands, and that the protein cannot stably bind heme if any of them is absent. Recombinant Dcytb was reduced by ascorbate under anaerobic conditions, the extent of reduction being 67% of that produced by dithionite. It was readily reoxidized by ferricyanide. EPR spectroscopy showed signals from low-spin ferriheme, consistent with bis-histidine coordination. These comprised a signal at g_max = 3.7 corresponding to a highly anisotropic species, and another at g_max = 3.18; these species are similar to those observed in other cytochromes of the b₅₆₁ family, and were reducible by ascorbate. In addition another signal was observed in some preparations at g_max = 2.95, but this was unreactive with ascorbate. Redox titrations indicated an average midpoint potential for the hemes in Dcytb of + 80 mV ± 30 mV; the data are consistent with either two hemes at the same potential, or differing in potential by up to 60 mV. These results indicate that Dcytb is similar to the ascorbate-reducible cytochrome b₅₆₁ of the adrenal chromaffin granule, though with some differences in midpoint potentials of the hemes.     

Properties of two distinct heme centers of cytochrome b561 from bovine chromaffin vesicles studied by EPR, resonance Raman, and ascorbate reduction assay

Cytochrome b(561) from bovine adrenal chromaffin vesicles contains two hemes b with different midpoint potentials (+150 and +60 mV) and participates in transmembrane electron transport from extravesicular ascorbate to an intravesicular monooxygenase, dopamine beta-hydroxylase. Treatment of oxidized cytochrome b(561) with diethylpyrocarbonate caused a downshift of midpoint potential for the lower component, and this shift was prevented by the presence of ascorbate during the treatment. Present EPR analyses showed that, upon the treatment, the g(z) = 3.69 heme species was converted to a non-ascorbate-reducible form, although its g(z)-value showed no appreciable change. The treatment had no effect on the other heme (the g(z) = 3.13 species). Raman data indicated that the two heme b centers adopt a six-coordinated low-spin state, in both the reduced and oxidized forms. There was no significant effect of diethylpyrocarbonate-treatment on the Raman spectra of either form, but the reducibility by ascorbate differed significantly between the two hemes upon the treatment. The addition of ferrocyanide enhanced both the reduction rate and final reduction level of the diethylpyrocarbonate-treated cytochrome b(561) when ascorbate was used as a reductant. This observation suggests that ferrocyanide scavenges monodehydroascorbate radicals produced by the univalent oxidation of ascorbate and, thereby, increases both the reduction rate and the final reduction level of the heme center on the intravesicular side of the diethylpyrocarbonate-treated cytochrome. These results further clarify the physiological role of this heme center as the electron donor to the monodehydroascorbate radical.     

Stopped-flow analyses on the reaction of ascorbate with cytochrome b561 purified from bovine chromaffin vesicle membranes

Cytochrome b(561) in adrenal chromaffin vesicle membranes conveys electron equivalents from extravesicular ascorbate to the intravesicular monodehydroascorbate radical. We conducted a stopped-flow study on the reaction of ascorbate with purified cytochrome b(561) in the detergent-solubilized state for the first time. The time course of the reduction of oxidized cytochrome b(561) with ascorbate could not be fitted with a single exponential but with a linear combination of at least four exponential functions. This result is consistent with the notion that cytochrome b(561) contains two hemes b, each having a distinct redox potential and a function upon reactions with ascorbate and monodehydroascorbate radical. The fastest phase, which was assigned to the first one-electron donation from ascorbate to heme b on the extravesicular side, was further analyzed by transient phase kinetics employing a two-step bi-uni sequential ordered mechanism. The result showed K(s) = 2.2 mM for ascorbate at pH6.0. At a region below pH5.5, there was a significant lag before the reduction of hemes b occurred. This time lag was interpreted as due to a pH-dependent transient state before the first electron transfer to take place. The fastest phase was completely lost by N-carbethoxylation of heme-coordinating histidyl residues (His88 and His161) and Lys85 upon treatment with diethylpyrocarbonate. The presence of ascorbate during the treatment inhibited the N-carbethoxylation of the histidyl residues and, thereby, restored the final reduction level of hemes b. But the reduction rate was still only one-twentieth of the native form. This result suggested an important role of the conserved Lys85 for the interaction with ascorbate.     

Evidence for an essential histidine residue in the ascorbate-binding site of cytochrome b561

Cytochrome b(561) mediates equilibration of the ascorbate/semidehydroascorbate redox couple across the membranes of secretory vesicles. The cytochrome is reduced by ascorbic acid and oxidized by semidehydroascorbate on either side of the membrane. Treatment with diethyl pyrocarbonate (DEPC) inhibits reduction of the cytochrome by ascorbate, but this activity can be restored by subsequent treatment with hydroxylamine, suggesting the involvement of an essential histidine residue. Moreover, DEPC inactivates cytochrome b(561) more rapidly at alkaline pH, consistent with modification of a histidine residue. DEPC does not affect the absorption spectrum of cytochrome b(561) nor does it change the midpoint reduction potential, confirming that histidine modification does not affect the heme. Ascorbate protects the cytochrome from inactivation by DEPC, indicating that the essential histidine is in the ascorbate-binding site. Further evidence for this is that DEPC treatment inhibits oxidation of the cytochrome by semidehydroascorbate but not by ferricyanide. This supports a reaction mechanism in which ascorbate loses a hydrogen atom by donating a proton to histidine and transferring an electron to the heme.     

Photo-induced cyclic electron transfer involving cytochrome bc1 complex and reaction center in the obligate aerobic phototroph Roseobacter denitrificans.

Flash-induced redox changes of b-type and c-type cytochromes have been studied in chromatophores from the aerobic photosynthetic bacterium Roseobacter denitrificans under redox-controlled conditions. The flash-oxidized primary donor P+ of the reaction center (RC) is rapidly re-reduced by heme H1 (Em,7 = 290 mV), heme H2 (Em,7 = 240 mV) or low-potential hemes L1/L2 (Em,7 = 90 mV) of the RC-bound tetraheme, depending on their redox state before photoexcitation. By titrating the extent of flash-induced low-potential heme oxidation, a midpoint potential equal to -50 mV has been determined for the primary quinone acceptor QA. Only the photo-oxidized heme H2 is re-reduced in tens of milliseconds, in a reaction sensitive to inhibitors of the bc1 complex, leading to the concomitant oxidation of a cytochrome c spectrally distinct from the RC-bound hemes. This reaction involves cytochrome c551 in a diffusional process. Participation of the bc1 complex in a cyclic electron transfer chain has been demonstrated by detection of flash-induced reduction of cytochrome b561, stimulated by antimycin and inhibited by myxothiazol. Cytochrome b561, reduced upon flash excitation, is re-oxidized slowly even in the absence of antimycin. The rate of reduction of cytochrome b561 in the presence of antimycin increases upon lowering the ambient redox potential, most likely reflecting the progressive prereduction of the ubiquinone pool. Chromatophores contain approximately 20 ubiquinone-10 molecules per RC. At the optimal redox poise, approximately 0.3 cytochrome b molecules per RC are reduced following flash excitation. Cytochrome b reduction titrates out at Eh < 100 mV, when low-potential heme(s) rapidly re-reduce P+ preventing cyclic electron transfer. Results can be rationalized in the framework of a Q-cycle-type model.     

His92 and His110 selectively affect different heme centers of adrenal cytochrome b(561)

Adrenal cytochrome b(561) (cyt b(561)), a transmembrane protein that shuttles reducing equivalents derived from ascorbate, has two heme centers with distinct spectroscopic signals and reactivity towards ascorbate. The His54/His122 and His88/His161 pairs furnish axial ligands for the hemes, but additional amino acid residues contributing to the heme centers have not been identified. A computational model of human cyt b(561) (Bashtovyy, D., Berczi, A., Asard, H., and Pali, T. (2003) Protoplasma 221, 31-40) predicts that His92 is near the His88/His161 heme and that His110 abuts the His54/His122 heme. We tested these predictions by analyzing the effects of mutations at His92 or His110 on the spectroscopic and functional properties. Wild type cytochrome and mutants with substitutions in other histidine residues or in Asn78 were used for comparison. The largest lineshape changes in the optical absorbance spectrum of the high-potential (b(H)) peak were seen with mutation of His92; the largest changes in the low-potential (b(L)) peak lineshape were observed with mutation of His110. In the EPR spectra, mutation of His92 shifted the position of the g=3.1 signal (b(H)) but not the g=3.7 signal (b(L)). In reductive titrations with ascorbate, mutations in His92 produced the largest increase in the midpoint for the b(H) transition; mutations in His110 produced the largest decreases in DeltaA(561) for the b(L) transition. These results indicate that His92 can be considered part of the b(H) heme center, and His110 part of the b(L) heme center, in adrenal cyt b(561).     

Two hemes in Bacillus subtilis succinate:menaquinone oxidoreductase (complex II).

Succinate:menaquinone-7 oxidoreductase (complex II) of the Gram-positive bacterium Bacillus subtilis consists of equimolar amounts of three polypeptides; a 65-kDa FAD-containing polypeptide, a 28-kDa iron-sulfur cluster containing polypeptide, and a 23-kDa membrane-spanning cytochrome b558 polypeptide. The enzyme complex was overproduced 2-3-fold in membranes of B. subtilis cells containing the sdhCAB operon on a low copy number plasmid and was purified in the presence of detergent. The cytochrome b558 subunit alone was similarly overexpressed in a complex II deficient mutant and partially purified. Isolated complex II catalyzed the reduction of various quinones and also quinol oxidation. Both activities were efficiently albeit not completely blocked by 2-n-heptyl-4-hydroxyquinoline N-oxide. Chemical analysis demonstrated two protoheme IX per complex II. One heme component was found to have an Em,7.4 of +65 mV and an EPR gmax signal at 3.68, to be fully reducible by succinate, and showed a symmetrical alpha-band absorption peak at 555 nm at 77 K. The other heme component was found to have an Em,7.4 of -95 mV and an EPR gmax signal at 3.42, was not reducible by succinate under steady-state conditions, and showed in the reduced state an apparent split alpha-band absorption peak with maxima at 553 and 558 nm at 77 K. Potentiometric titrations of partially purified cytochrome b558 subunit demonstrated that the isolated cytochrome b558 also contains two hemes. Some of the properties, i.e., the alpha-band light absorption peak at 77 K, the line shapes of the EPR gmax signals, and reactivity with carbon monoxide were observed to be different in B. subtilis cytochrome b558 isolated and in complex II. This suggests that the bound flavoprotein and iron-sulfur protein subunits protect or affect the heme environment in the assembled complex.     

Assignment of individual heme EPR signals of Desulfovibrio baculatus (strain 9974) tetraheme cytochrome c3. A redox equilibria study

An EPR redox titration was performed on the tetraheme cytochrome c3 isolated from Desulfovibrio baculatus (strain 9974), a sulfate-reducer. Using spectral differences at different poised redox states of the protein, it was possible to individualize the EPR g-values of each of the four hemes and also to determine the mid-point redox potentials of each individual heme: heme 4 (-70 mV) at gmax = 2.93, gmed = 2.26 and gmin = 1.51; heme 3 (-280 mV) at gmax = 3.41; heme 2 (-300 mV) at gmax = 3.05, gmed = 2.24 and gmin = 1.34; and heme 1 (-355 mV) at gmx = 3.18. A previously described multi-redox equilibria model used for the interpretation of NMR data of D. gigas cytochrome c3 [Santos, H., Moura, J.J.G., Moura, I., LeGall, J. & Xavier, A. V. (1984) Eur. J. Biochem. 141, 283-296] is discussed in terms of the EPR results.     

High-yield production, purification and characterization of functional human duodenal cytochrome b in an Escherichia coli system

Human duodenal cytochrome b (Dcytb) is a transmembrane hemoprotein found in the duodenal brush border membrane and in erythrocytes. Dcytb has been linked to uptake of dietary iron and to ascorbate recycling in erythrocytes. Detailed biophysical and biochemical characterization of Dcytb has been limited by difficulties in expressing sufficient amounts of functional recombinant protein in yeast and insect cell systems. We have developed an Escherichia coli Rosetta-gami B(DE3) cell system for production of recombinant His-tagged human Dcytb with a yield of ～26 mg of purified, ascorbate-reducible cytochrome per liter of culture. The recombinant protein is readily solubilized with n-dodecyl-β-D-maltoside and purified to electrophoretic homogeneity by one-step chromatography on cobalt affinity resin. The purified recombinant Dcytb has a heme to protein ratio very close to the theoretical value of 2 and retains functional reactivity with ascorbate, as assessed by spectroscopic and kinetic measurements. Ascorbate showed a marked kinetic selectivity for the high-potential heme center over the low-potential heme center in purified Dcytb. This new E. coli expression system for Dcytb offers ～7-fold improvement in yield and other substantial advantages over existing expression systems for reliable production of functional Dcytb at levels suitable for biochemical, biophysical and structural characterization.     

Purification, redox and spectroscopic properties of the tetraheme cytochrome c isolated from Rubrivivax gelatinosus.

The tetraheme cytochrome c subunit of the Rubrivivax gelatinosus reaction center was isolated in the presence of octyl beta-D-thioglucoside by ammonium sulfate precipitation and solubilization at pH 9 in a solution of Deriphat 160. Several biochemical properties of this purified cytochrome were characterized. In particular, it forms small oligomers and its N-terminal amino acid is blocked. In the presence or absence of diaminodurene, ascorbate and dithionite, different oxidation/reduction states of the isolated cytochrome were studied by absorption, EPR and resonance Raman spectroscopies. All the data show two hemes quickly reduced by ascorbate, one heme slowly reduced by ascorbate and one heme only reduced by dithionite. The quickly ascorbate-reduced hemes have paramagnetic properties very similar to those of the two low-potential hemes of the reaction center-bound cytochrome (gz = 3.34), but their alpha band is split with two components peaking at 552 nm and 554 nm in the reduced state. Their axial ligands did not change, being His/Met and His/His, as indicated by the resonance Raman spectra. The slowly ascorbate-reduced heme and the dithionite-reduced heme are assigned to the two high-potential hemes of the bound cytochrome. Their alpha band was blue-shifted at 551 nm and the gz values decreased to 2.96, although the axial ligations (His/Met) were conserved. It was concluded that the estimated 300 mV potential drop of these hemes reflected changes in their solvent accessibility, while the reduction in gz indicates an increased symmetry of their cooordination spheres. These structural modifications impaired the cytochrome's essential function as the electron donor to the photooxidized bacteriochlorophyll dimer of the reaction center. In contrast to its native state, the isolated cytochrome was unable to reduce efficiently the reaction center purified from a Rubrivivax gelatinosus mutant in which the tetraheme was absent. Despite the conformational changes of the cytochrome, its four hemes are still divided into two groups with a pair of low-potential hemes and a pair of high-potential hemes.     

Diethyl pyrocarbonate modification abolishes fast electron accepting ability of cytochrome b561 from ascorbate but does not influence electron donation to monodehydroascorbate radical: identification of the modification sites by mass spectrometric analysis

Cytochrome b(561) from bovine adrenal chromaffin vesicles contains two heme B prosthetic groups and transports electron equivalents across the vesicle membranes to convert intravesicular monodehydroascorbate radical to ascorbate. To elucidate the mechanism of the transmembrane electron transfer, effects of the treatment of purified cytochrome b(561) with diethyl pyrocarbonate, a reagent specific for histidyl residues, were examined. We found that when ascorbate was added to the oxidized form of diethyl pyrocarbonate-treated cytochrome b(561), less than half of the heme iron was reduced but with a very slow rate. In contrast, radiolytically generated monodehydroascorbate radical was oxidized rapidly by the reduced form of diethyl pyrocarbonate-modified cytochrome b(561), as observed for untreated cytochrome b(561). These results indicate that the heme center specific for the electron acceptance from ascorbate was perturbed by the modification of amino acid residues nearby. We identified the major modification sites by mass spectrometry as Lys85, His88, and His161, all of which are fully conserved and located on the extravesicular side of cytochrome b(561) in the membranes. We suggest that specific N-carbethoxylation of the histidyl ligands of the heme b at extravesicular side abolishes the electron-accepting ability from ascorbate.     

Selective perturbation of the intravesicular heme center of cytochrome b561 by cysteinyl modification with 4,4'-dithiodipyridine

Cytochrome b(561) from bovine adrenal chromaffin vesicles contains two hemes b with EPR signals at g(z) = 3.69 and 3.14 and participates in transmembrane electron transport from extravesicular ascorbate to an intravesicular monooxygenase, dopamine beta-hydroxylase. Treatment of purified cytochrome b(561) in an oxidized state with a sulfhydryl reagent, 4,4'-dithiodipyridine, caused the introduction of only one 4-thiopyridine group per b(561) molecule at either Cys57 or Cys125. About half of the heme centers of the modified cytochrome were reduced rapidly with ascorbate as found for the untreated sample, but the final reduction level decreased to approximately 65%. EPR spectra of the modified cytochrome showed that a part of the g(z) = 3.14 low-spin EPR species was converted to a new low-spin species with g(z) = 2.94, although a considerable part of the heme center was concomitantly converted to a high-spin g = 6 species. Addition of ascorbate to the modified cytochrome caused the disappearance or significant reduction of the EPR signals at g(z) = 3.69 and 3.14 of low-spin species and at g = 6.0 of the high-spin species, but not for the g(z) approximately 2.94 species. These results suggested that the bound 4-thiopyridone at either Cys57 or Cys125 affected the intravesicular heme center and converted it partially to a non-ascorbate-reducible form. The present observations suggested the importance of the two well-conserved Cys residues near the intravesicular heme center and implied their physiological roles during the electron donation to the monodehydroascorbate radical.     

Structure of a novel c7-type three-heme cytochrome domain from a multidomain cytochrome c polymer

The structure of a novel c(7)-type cytochrome domain that has two bishistidine coordinated hemes and one heme with histidine, methionine coordination (where the sixth ligand is a methionine residue) was determined at 1.7 A resolution. This domain is a representative of domains that form three polymers encoded by the Geobacter sulfurreducens genome. Two of these polymers consist of four and one protein of nine c(7)-type domains with a total of 12 and 27 hemes, respectively. Four individual domains (termed A, B, C, and D) from one such multiheme cytochrome c (ORF03300) were cloned and expressed in Escherichia coli. The domain C produced diffraction quality crystals from 2.4 M sodium malonate (pH 7). The structure was solved by MAD method and refined to an R-factor of 19.5% and R-free of 21.8%. Unlike the two c(7) molecules with known structures, one from G. sulfurreducens (PpcA) and one from Desulfuromonas acetoxidans where all three hemes are bishistidine coordinated, this domain contains a heme which is coordinated by a methionine and a histidine residue. As a result, the corresponding heme could have a higher potential than the other two hemes. The apparent midpoint reduction potential, E(app), of domain C is -105 mV, 50 mV higher than that of PpcA.     

Chromaffin granule membranes contain at least three heme centers: direct evidence from EPR and absorption spectroscopy

Low-temperature electron paramagnetic resonance (EPR) spectroscopy, circular dichroism and two-component redox titration have previously provided evidence for two different ascorbate-reducible heme centers in cytochrome b(561) present in chromaffin granule membranes. These species have now been observed by room and liquid nitrogen temperature absorption spectroscopy. The visualization of these heme centers becomes possible as a consequence of utilizing chromaffin granule membranes prepared by a mild procedure. Additionally, a new redox center, not reducible by ascorbate, was discovered by both EPR and absorption spectroscopy. It constitutes about 15% of the heme absorbance of chromaffin membranes at 561 nm and has EPR characteristics of a well-organized highly axial low-spin heme center (thus making it unlikely that it is a denatured species). This species is either an alternative form of one of the hemes of cytochrome b(561) that has a very low redox potential or a b-type cytochrome distinct from b(561).     

Axial ligation and stoichiometry of heme centers in adrenal cytochrome b561

Cytochrome (cyt) b561 transports electrons across the membrane of chromaffin granules (CG) present in the adrenal medulla, supporting the biosynthesis of norepinephrine in the CG matrix. We have conducted a detailed characterization of cyt b561 using electron paramagnetic resonance (EPR) and optical spectroscopy on the wild-type and mutant forms of the cytochrome expressed in insect cells. The gz = 3.7 (low-potential heme) and gz = 3.1 (high-potential heme) signals were found to represent the only two authentic hemes of cyt b561; models that propose smaller or greater amounts of heme can be ruled out. We identified the axial ligands to hemes in cyt b561 by mutating four conserved histidines (His54 and His122 at the matrix-side heme center and His88 and His161 at the cytoplasmic-side heme center), thus confirming earlier structural models. Single mutations of any of these histidines produced a constellation of spectroscopic changes that involve not one but both heme centers. We hypothesize that the two hemes and their axial ligands in cyt b561 are integral parts of a structural unit that we term the "kernel". Histidine to glutamine substitutions in the cytoplasmic-side heme center but not in the matrix-side heme center led to the retention of a small fraction of the low-potential heme with gz = 3.7. We provisionally assign the low-potential heme to the matrix side of the membrane; this arrangement suggests that the membrane potential modulates electron transport across the CG membrane.     

Membrane-bound cytochromes in Chloroflexus aurantiacus studied by EPR.

The heme components of chlorosome-depleted membranes of the green-gliding bacterium Chloroflexus aurantiacus were studied by EPR spectroscopy. The four major species, which are present in approximately equimolar quantities, are characterized by the following gz values, redox midpoint potentials and orientations of heme planes with respect to the plane of the membrane: gz = 3.40, Em = +280 mV, 30 degrees; gz = 3.33, Em = 0 mV, 45 degrees; gz = 3.03, Em = +95 mV, 40-50 degrees and gz = 2.95, Em = +150 mV, 90 degrees. These four hemes were attributed to cytochrome c554, the membrane-bound immediate electron donor to the photosynthetic reaction centre in Chloroflexus. All hemes except that with the highest potential were able to undergo photooxidation at 4 K. The photooxidation of the lowest potential heme was stable, whereas that of the +95 mV and the +150 mV hemes reversed on increasing the temperature to 100 K in darkness, due to charge recombination. The ability to photooxidize these hemes at 4 K was lost upon aging of samples. The results demonstrate that a reaction-centre-associated tetraheme cytochrome subunit, analogous to that of purple bacteria, is also present in C. aurantiacus.     

Isolation and characterization of the membrane-bound cytochrome c-554 from the thermophilic green photosynthetic bacterium Chloroflexus aurantiacus

The membrane-bound photooxidizable cytochrome c-554 from Chloroflexus aurantiacus has been purified. The purified protein runs as a single heme staining band on SDS-PAGE with an apparent molecular mass of 43 000 daltons. An extinction coefficient of 28 ± 1 mM^–1 cm^–1 per heme at 554 nm was found for the dithionite-reduced protein. The potentiometric titration of the hemes takes place over an extended range, showing clearly that the protein does not contain a single heme in a well-defined site. The titration can be fit to a Nernst curve with midpoint potentials at 0, +120, +220 and +300 mV vs the standard hydrogen electrode. Pyridine hemochrome analysis combined with a Lowry protein assay and the SDS-PAGE molecular weight indicates that there are a minimum of three, and probably four hemes per peptide. Amino acid analysis shows 5 histidine residues and 29% hydrophobic residues in the protein. This cytochrome appears to be functionally similar to the bound cytochrome from Rhodopseudomonas viridis. Both cytochrome c-554 from C. aurantiacus and the four-heme cytochrome c-558-553 from R. viridis appear to act as direct electron donors to the special bacteriochlorophyll pair of the photosynthetic reaction center. They have a similar content of hydrophobic amino acids, but differ in isoelectric point, thermodynamic characteristics, spectral properties, and in their ability to be photooxidized at low temperature.Abbreviations LDAO lauryl dimethyl amine-N-oxide - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - mV millivolt - E_m.8 midpoint potential at pH 8.0 - ODV optical density x volume in ml     

Ascorbate inhibits the carbethoxylation of two histidyl and one tyrosyl residues indispensable for the transmembrane electron transfer reaction of cytochrome b561

Cytochrome b(561) from bovine adrenal chromaffin vesicles contains two heme B prosthetic groups and transports electron equivalents across the vesicle membranes to convert intravesicular monodehydroascorbate radical to ascorbate. We found previously that treatment of oxidized cytochrome b(561) with diethyl pyrocarbonate caused specific N-carbethoxylation of three fully conserved residues (His88, His161, and Lys85) located at the extravesicular side. The modification lead to a selective loss of the electron-accepting ability from ascorbate without affecting the electron donation to monodehydroascorbate radical [Tsubaki, M., Kobayashi, K., Ichise, T., Takeuchi, F., and Tagawa, S. (2000) Biochemistry 39, 3276-3284]. In the present study, we found that these modifications lead to a drastic decrease of the midpoint potential of heme b at the extravesicular side from +60 to -30 mV. We found further that the O-carbethoxylation of one tyrosyl residue (Tyr218) located at the extravesicular side was significantly enhanced under alkaline conditions, leading to a very slow reduction process of the oxidized heme b with ascorbate. On the other hand, the presence of ascorbate during the treatment with diethyl pyrocarbonate was found to suppress the carbethoxylation of His88, His161, and Tyr218, whereas the modification level of Lys85 was not affected. Concomitantly, the final reduction level of heme b with ascorbate was protected, although the fast reduction phase was not fully restored. These results suggest that the two heme-coordinating histidyl residues (His88 and His161) are also a part of the ascorbate binding site. Tyr218 and Lys85 may have a role in the recognition/binding process for ascorbate and are indispensable for the fast electron transfer reaction.     

Stopped-flow and rapid-scan studies of the redox behavior of cytochrome aco from facultative alkalophilic Bacillus

Cytochrome aco purified from an alkalophilic bacterium grown at pH 10 contains hemes a, b, and c as prosthetic groups, and their redox behavior was examined by using stopped-flow and rapid-scan techniques. Under anaerobic conditions the reduction of both heme a and c moieties with dithionite proceeded exponentially but with different rates, usually the former being reduced about 4 times faster than the latter. The reduction of protoheme was much slower, and a time-difference spectrum for this species was of a high spin type with absorption peaks at 433, 557, and 609 nm. Only the protoheme combined with CO, fulfilling the criteria for cytochrome o. Potentiometric titrations determined a midpoint potential of c heme to be 95 mV at pH 7.0 and 25 degrees C and suggested the presence of two forms of a heme with midpoint potentials of 250 and 323 mV. Cytochrome aco utilizes ascorbate plus N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) to reduce oxygen relatively rapidly without added cytochrome c (Qureshi, M. H., Yumoto, I., Fujiwara, T., Fukumori, Y., Yamanaka, T. (1990) J. Biochem. 107, 480-485). During the steady state, however, heme a stayed almost fully reduced in contrast to a partial reduction of heme c. Even after exhaustion of the dissolved oxygen the extent of reduction of heme c was 60-70% that attained by the dithionite reduction. When ascorbate plus TMPD-reduced cytochrome aco was exposed to oxygen the reduced heme c was oxidized rapidly whereas the oxidation of reduced a heme was negligibly slow. The full reduction of heme a during the steady state and its extremely slow oxidation rendered participation of heme a in the oxidase reaction less likely. A novel peak appearing transiently around 567 nm during the reaction was tentatively ascribed to an intermediate form of protoheme, or o heme, which was thus supposed to react directly with molecular oxygen. These results suggest strongly that the main electron transfer pathway would be c----o----oxygen. A possible role of a in regulating the electron flow through the main pathway and its functional relationship to a heme in the aa3-type cytochrome oxidase were discussed.     

Purification and spectropotentiometric characterization of Escherichia coli NrfB, a decaheme homodimer that transfers electrons to the decaheme periplasmic nitrite reductase complex

Escherichia coli can reduce nitrite to ammonium via a 120-kDa decaheme homodimeric periplasmic nitrite reductase (NrfA) complex. Recent structure-based spectropotentiometric studies are shedding light on the catalytic mechanism of NrfA; however, electron input into the enzyme has not been addressed biochemically. This study reports the first purification of NrfB, a novel 20-kDa pentaheme c-type cytochrome encoded by the nrfB gene that follows the nrfA gene in many bacterial nrf operons. Analyses by gel filtration demonstrated that NrfB purifies as a decaheme homodimer. Analysis of NrfB by UV-visible and magnetic circular dichroism spectroscopy demonstrates that all five NrfB ferric heme irons are low spin and are most likely coordinated by two axial histidine ligands. Spectropotentiometry revealed that the midpoint redox potentials of five ferric hemes were in the low potential range of 0 to -400 mV. Analysis by low temperature EPR spectroscopy revealed signals that arise from two classes of bis-His ligated low spin hemes, namely a rhombic trio at g(1,2,3) = 2.99, 2.27, and 1.5 that arises from two hemes in which the planes of histidine imidazole rings are near-parallel and a large g(max) signal at g = 3.57 that arises from three hemes in which the planes of the histidine imidazole rings are near-perpendicular. NrfB was also overexpressed as a recombinant protein, which had similar spectropotentiometric properties as the native protein. Reconstitution experiments demonstrated that the reduced decaheme NrfB dimer could serve as a direct electron donor to the oxidized decaheme NrfA dimer, thus forming a transient 20-heme [NrfB](2)[NrfA](2) electron transfer complex.