Fast cytochrome bo from Escherichia coli binds two molecules of nitric oxide at CuB

The reaction of nitric oxide (NO) with fast cytochrome bo from Escherichia coli has been studied by electronic absorption, MCD, and EPR spectroscopy. Titration of the enzyme with NO showed the formation of two distinct species, consistent with NO binding stoichiometries of 1:1 and 2:1 with observed dissociation constants at pH 7.5 of approximately 2.3 x 10(-)6 and 3.3 x 10(-)5 M. Monitoring the titration by EPR spectroscopy revealed that the broad EPR signals at g approximately 7.3, 3.7, and 2.8 due to magnetic interaction between high-spin heme o (S = 5/2) and CuBII (S = 1/2) are lost. A high-spin heme o signal at g = 6.0 appears as the 1:1 complex is formed but is lost again on formation of the 2:1 complex, which is EPR silent. The absorption spectrum shows that heme o remains in the high-spin FeIII state throughout the titration. These results are consistent with the binding of up to two NO molecules at CuBII. This has been confirmed by studies with the Cl- adduct of fast cytochrome bo. MCD evidence shows that heme o remains ligated by histidine and water. Addition of excess NO to the Cl- adduct leads to the appearance of a high-spin FeIII heme EPR signal. Hence chloride ion binds to CuB, blocking the binding of a second NO molecule. These results suggest a mechanism for the reduction of NO to nitrous oxide by cytochrome bo and cytochrome c oxidase in which the binding of two cis NO molecules at CuB permits the formation of an N-N bond and the abstraction of oxygen by the heme group.     

Interaction of peroxynitrite with mitochondrial cytochrome oxidase. Catalytic production of nitric oxide and irreversible inhibition of enzyme activity

Purified mitochondrial cytochrome c oxidase catalyzes the conversion of peroxynitrite to nitric oxide (NO). This reaction is cyanide-sensitive, indicating that the binuclear heme a3/CuB center is the catalytic site. NO production causes a reversible inhibition of turnover, characterized by formation of the cytochrome a3 nitrosyl complex. In addition, peroxynitrite causes irreversible inhibition of cytochrome oxidase, characterized by a decreased Vmax and a raised Km for oxygen. Under these conditions, the redox state of cytochrome a is elevated, indicating inhibition of electron transfer and/or oxygen reduction reactions subsequent to this center. The lipid bilayer is no barrier to these peroxynitrite effects, as NO production and irreversible enzyme inhibition were also observed in cytochrome oxidase proteoliposomes. Addition of 50 microM peroxynitrite to 10 microM fully oxidized enzyme induced spectral changes characteristic of the formation of ferryl cytochrome a3, partial reduction of cytochrome a, and irreversible damage to the CuA site. Higher concentrations of peroxynitrite (250 microM) cause heme degradation. In the fully reduced enzyme, peroxynitrite causes a red shift in the optical spectrum of both cytochromes a and a3, resulting in a symmetrical peak in the visible region. Therefore, peroxynitrite can both modify and degrade the metal centers of cytochrome oxidase.     

Isolation and characterization of nitric oxide reductase from Paracoccus halodenitrificans

Nitric oxide reductase was isolated from the membrane fraction of a denitrifying bacterium, Paracoccus halodenitrificans, in the presence of n-dodecyl beta-D-maltoside. A relatively simple and effective procedure to purify NO reductase using DEAE-Toyopearl and hydroxyapatite (ceramic) chromatographies has been developed. The enzyme consisted of two subunits with molecular masses of 20 and 42 kDa associated with the c-type heme and two b-type hemes, respectively. The optical and magnetic circular dichroism (MCD) spectra of the oxidized (as isolated) and reduced enzymes indicated that the heme c is in the low-spin state and the hemes b are in the high- and low-spin states. The EPR spectrum also showed the presence of the split high-spin component (g perpendicular = 6.6, 6.0) and two low spin components (gz,y,x = 2.96, 2.26, 1.46, gz = 3.59). Although the presence of an extra iron was suggested from atomic absorption spectroscopy, a non-heme iron could not be detected by colorimetric titrations using ferene and 2-(5-nitro-2-pyridylazo)- 5-(N-propyl-N-sulfopropylamino)phenolate (PAPS). One of the extra signals at g = 4.3 and 2.00 might come from a non-heme iron, while they may originate from an adventitious iron and a certain nonmetallic radical, respectively. When CO acted on the reduced enzyme, both of the low-spin hemes were not affected, and when NO acted on the reduced enzyme, the optical and MCD spectra were of a mixture of the oxidized and reduced enzymes. Consequently, the reduction of NO was supposed to take place at the high-spin heme b. The heme c and the low-spin heme b centers were considered to function as electron mediators during the intermolecular and intramolecular processes.     

Ab initio determination of the crystal structure of cytochrome c6 and comparison with plastocyanin

BACKGROUND: Electron transfer between cytochrome f and photosystem I (PSI) can be accomplished by the heme-containing protein cytochrome c6 or by the copper-containing protein plastocyanin. Higher plants use plastocyanin as the only electron donor to PSI, whereas most green algae and cyanobacteria can use either, with similar kinetics, depending on the copper concentration in the culture medium. RESULTS: We report here the determination of the structure of cytochrome c6 from the green alga Monoraphidium braunii. Synchrotron X-ray data with an effective resolution of 1.2 A and the presence of one iron and three sulfur atoms enabled, possibly for the first time, the determination of an unknown protein structure by ab initio methods. Anisotropic refinement was accompanied by a decrease in the 'free' R value of over 7% the anisotropic motion is concentrated at the termini and between residues 38 and 53. The heme geometry is in very good agreement with a new set of heme distances derived from the structures of small molecules. This is probably the most precise structure of a heme protein to date. CONCLUSIONS: On the basis of this cytochrome c6 structure, we have calculated potential electron transfer pathways and made comparisons with similar analyses for plastocyanin. Electron transfer between the copper redox center of plastocyanin to PSI and from cytochrome f is believed to involve two sites on the protein. In contrast, cytochrome c6 may well use just one electron transfer site, close to the heme unit, in its corresponding reactions with the same two redox partners.     

Cytochrome c peroxidase from Methylococcus capsulatus Bath

A bacterial cytochrome c peroxidase was purified from the obligate methanotroph Methylococcus capsulatus Bath in either the fully oxidized or the half reduced form depending on the purification procedure. The cytochrome was a homo-dimer with a subunit mol mass of 35.8 kDa and an isoelectric point of 4.5. At physiological temperatures, the enzyme contained one high-spin, low-potential (Em7 = -254 mV) and one low-spin, high-potential (Em7 = +432 mM ) heme. The low-potential heme center exhibited a spin-state transition from the penta-coordinated, high-spin configuration to a low-spin configuration upon cooling the enzyme to cryogenic temperatures. Using M. capsulatus Bath ferrocytochrome c555 as the electron donor, the KM and Vmax for peroxide reduction were 510 +/- 100 nM and 425 +/- 22 mol ferrocytochrome c555 oxidized min-1 (mole cytochrome c peroxidase)-1, respectively.     

Electron transfer proteins from the haloalkaliphilic archaeon Natronobacterium pharaonis: possible components of the respiratory chain include cytochrome bc and a terminal oxidase cytochrome ba3

Natronobacterium pharaonis, an aerobic haloalkaliphilic archaebacterium, expresses high concentrations of redox proteins as do alkaliphilic eubacteria. The first redox protein characterized from N. pharaonis was halocyanin [Scharf, B., & Engelhard, M. (1993) Biochemistry 32, 12894-12900], a small blue copper protein. It is a peripheral membrane protein and is conjectured to function in a manner similar to plastocyanin. In the present work, the respiratory chain is further elucidated and the purification and characterization of the most abundant components cytochrome bc and cytochrome ba3 from the membrane fraction are described. The cytochrome bc complex consists of a 14 and an 18 kDa subunit in a 1:1 ratio, with heme c bound to the larger polypeptide. An Fe-S subunit similar to that found in eukaryotic bc complexes has not yet been identified. The second membrane complex carries two different heme groups of the ba3-type as well as copper. It contains two subunits of 36 and 40 kDa. This cytochrome ba3 binds carbon monoxide, a feature common to terminal oxidases. There is no spectroscopic evidence for a second terminal oxidase; hence, under the growth conditions chosen the respiratory chain of N. pharaonis appears to be unbranched. In addition to these cytochromes, a succinate dehydrogenase which is solubilized from the membrane by detergents was isolated. A cytochrome c which was isolated from the cytosol has an unusually high molecular weight and a redox potential of -142 mV. A second cytosolic protein, ferredoxin, was purified to homogeneity. A comparison of the redox potentials of the isolated proteins with those obtained from the native membrane allows the construction of a possible electron transfer chain.     

Localization of the heme binding region in soluble guanylate cyclase

Soluble guanylate cyclase (sGC) is a heterodimeric hemoprotein composed of alpha1 and beta1 subunits. sGC is activated by nitric oxide (NO) and therefore plays a central role in NO signal transduction. Activation of sGC by NO is believed to be mediated by the interaction between NO and the heme of sGC. Spectroscopic and kinetic studies have shown that the heme of sGC is in a unique environment. Characterization of the heme environment is critical to the understanding of the mechanism of NO activation. To approach this goal, the beta1 N-terminal fragment consisting of residues 1-385 [beta1(1-385)] of sGC was expressed in E. coli. beta1(1-385) was then purified to homogeneity in two steps by DEAE ion exchange and gel filtration chromatography. Purified beta1(1-385) was found to contain a stoichiometric amount of heme. The UV-visible spectrum of beta1(1-385) is almost identical to that of the native heterodimeric sGC purified from bovine lung. beta1(1-385) binds both NO and CO, leading to a shift in the Soret maximum from 431 nm to 398 and 423 nm, respectively. These spectral shifts are identical to those observed with heterodimeric sGC purified from bovine lung. These results suggest that the heme in the beta1(1-385) is similar to that in the heterodimeric sGC. Therefore, for the first time, the heme binding region of sGC has been unambiguously localized to the N-terminal region of the beta1 subunit. Our data also suggest that the N-terminal region of the beta1 subunit of sGC is itself sufficient for heme binding.     

Characterization of a cb-type cytochrome c oxidase from Helicobacter pylori

Helicobacter pylori is a microaerophilic Gram-negative spiral bacterium residing in human stomach. A cb-type cytochrome c oxidase that terminates the respiratory chain was purified to near homogeneity by solubilizing the membranes with Triton X-100 and applying anion exchange, Cu-chelating, and gel filtration chromatographies. Redox- and CO-difference spectra and pyridine ferrohaemochrome analysis showed the enzyme to contain three haems C, one low-spin protohaem, and one high-spin protohaem that probably forms a dioxygen-reducing bimetalic center with a copper atom. The enzyme actively oxidizes soluble cytochrome c from this bacterium (TNmax of about 250 s-1) with a Km of 0.9 microM. Yeast cytochrome c and N,N,N',N'-tetramethyl p-phenylenediamine (TMPD) are also oxidized at similar maximal velocities with larger Km's. Oxygen pulse experiments on resting cells in the presence of ascorbate plus TMPD or L-lactate indicated that this sole terminal oxidase pumps H+, although the H+ pumping activity by proteoliposomes reconstituted from the enzyme and P-lipids was low. Two main bands with haem C at 58 and 26 kDa were observed upon polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and succeeding protein and haem staining. Sequencing of the operon encoding the subunits of the enzyme revealed the presence of ccoNOQP. N-terminal analysis of the 58 kDa band showed 15 or 13 amino acids coinciding with the amino acid sequences deduced from the DNA of ccoN and ccoO. CcoN, the largest subunit bearing two protohaems and copper, and ccoO, a mono-haem cytochrome subunit form a protein complex with an apparent molecular mass of 58 kDa, even in the presence of sodium dodecyl sulfate. The 26 kDa band is tentatively assumed to be ccoP with two haems C.     

Oxidative titrations of reduced cytochrome aa3: correlation of midpoint potentials and extinction coefficients observed at three major absorption bands

Anaerobic oxidative titrations of purified cytochrome aa3 were monitored at three wavelengths (444, 604, and 820 nm), in both the absence and the presence of carbon monoxide. Computer simulation of each titration curve was utilized to ascertain the midpoint potentials of the four oxidation-reduction centers of the enzyme. For experiments performed under nitrogen, two components were found to titrate with low potential (heme aL = 220 mV, CuL = 240 mV) and two with high potential (heme ath, cuH = 340 mV), consistent with results obtained previously in reductive titrations. Unequal heme extinction coefficients were observed at 444 nm. Oxidation by either potassium ferricyanide or 1,1'-bis(hydroxymethyl)ferricinium ion showed that the low potential heme component contributed 75% of the absorbance change at 444 nm. At 820 nm, the entire absorbance change could be attributed to a single, low potential copper component. Midpoint potentials calculated for the carbon monoxide complexed enzyme agreed with previously reported values. The copper components retained the values observed under nitrogen, while the titratable heme group gave an apparent midpoint potential of 260 mV. These results enable us to assign absorbance changes at various wavelengths to specific redox components of cytochrome aa3.     

L-thiocitrulline. A stereospecific, heme-binding inhibitor of nitric-oxide synthases

Nitric-oxide synthase (NOS) catalyzes the oxidation of L-arginine to citrulline and nitric oxide (NO). The enzyme is inhibited by a variety of N omega-monosubstituted L-arginine analogs, and some of these compounds are useful in reversing pathologies associated with the overproduction of NO (e.g. the hypotension of septic shock). We report here that L-thiocitrulline (gamma-thioureido-L-norvaline) is a potent, stereospecific inhibitor of the constitutive brain and endothelial isoforms of NOS as well as the isoform induced in vascular smooth muscle cells by lipopolysaccharide and interferon-gamma. Steady state kinetic studies show L-thiocitrulline inhibition is competitive with L-arginine (Ki approximately 4-20% of KArgm), indicating that initial binding is as a substrate/product analog. In contrast to L-arginine and N omega-methyl-L-arginine, the prototypic NOS inhibitor, L-thiocitrulline binding elicits a "Type II" difference spectrum, indicating a high spin to low spin transition of the iron in the heme cofactor. This finding suggests that L-thiocitrulline is contributing the sixth ligand to heme iron, probably through the thioureido sulfur. Such interaction with heme iron neither stimulates nor inhibits the direct flavin-mediated cytochrome c reduction activity of the enzyme, but it does inhibit heme-dependent superoxide formation. In vivo, L-thiocitrulline is a potent pressor agent in both normal and endotoxemic rats, the latter finding suggesting utility in treating the hypotension of septic shock.     

How replacements of the 12 conserved histidines of subunit I affect assembly, cofactor binding, and enzymatic activity of the Bradyrhizobium japonicum cbb3-type oxidase

Alignments of the amino acid sequences of subunit I (FixN or CcoN) of the cbb3-type oxidases show 12 conserved histidines. Six of them are diagnostic of heme-copper oxidases and are thought to bind the following cofactors: the low spin heme B and the binuclear high spin heme B-CuB center. The other six are FixN(CcoN)-specific and their function is unknown. To analyze the contribution of these 12 invariant histidines of FixN in cofactor binding and function of the Bradyrhizobium japonicum cbb3-type oxidase, they were substituted by valine or alanine by site-directed mutagenesis. The H131A mutant enzyme had already been reported previously to be defective in oxidase assembly and function (Zufferey, R., Th?ny-Meyer, L., and Hennecke, H. (1996) FEBS Lett. 394, 349-352). Four of the remaining histidines were not essential for activity or assembly (positions 226, 246, 333, and 457); by contrast, histidines 331, 410, and 418 were required both for activity and stability of the enzyme. The last group of mutant enzymes, H420A, H280A, H330A, and H316V, were assembled but not functional. To purify the latter mutant proteins and the wild-type enzyme, a six-histidine tag was added to the C terminus of subunit I. The His6-tagged cbb3-oxidase complexes were purified 20-fold by a three-step purification protocol. With the exception of the H420A mutant oxidase, the mutant enzymes H280A, H316V, and H331A contained normal amounts of copper and heme B, and they displayed similar visible light spectroscopic characteristics like the wild-type His6-tagged enzyme. The His6-tagged H420A mutant oxidase differed from the His6-tagged wild-type protein by showing altered visible light spectroscopic characteristics. No stable mutant oxidase lacking copper or heme B was obtained. This strongly suggests that copper and heme B incorporations in subunit I are prerequisites for assembly of the enzyme.     

Existence of two heme B centers in cytochrome b561 from bovine adrenal chromaffin vesicles as revealed by a new purification procedure and EPR spectroscopy

We have established a new purification procedure of cytochrome b561 from bovine adrenomedullary chromaffin vesicles. The heme content analysis of the purified sample indicated the presence of 1.7 molecules of heme B/cytochrome b561 molecule. EPR spectroscopy of the purified enzyme in oxidized state showed that there were three types of low spin heme species. Two of them showed usual EPR signals at gz = 3.14 and gz = 2.84 arising from the same heme and were interconvertible depending on pH. The other species showed a highly anisotropic low spin signal at gz = 3.70, with a lower redox potential than the others, and a temperature-sensitive character. These properties are very similar to low potential cytochrome b (bL or b566) of the mitochondrial complex III, indicating that the gz = 3.70 species is derived from a heme component different from the one that shows the usual low spin EPR signals. Based on our new structural model, these two heme B prosthetic groups are likely to be located on both sides of the membranes in close contact with the ascorbic acid- and semidehydroascorbic acid-binding sites, respectively, to facilitate the electron transfer across the membranes. This molecular architecture may provide a structural basis for the transmembrane electron transfer catalyzed by this hemoprotein.     

Purification of the cyclooxygenase that forms prostaglandins. Demonstration of two forms of iron in the holoenzyme

The fatty acid cyclooxygenase (ec 1.14.99.1) that produces the prostaglandin and thromboxane precursor, 15-hydroperoxy-9 alpha, 11 alpha-peroxidoprosta-5, 13-dienoic acid (PGG2), has been purified from sheep vesicular glands to a specific activity of 46,000 units/mg of protein by combining detergent solubilization, (NH4)SO4 fractionation, chromatography on DEAE-cellulose and Flurbiprofen-Sepharose, isoelectric focusing, and gel filtration. The final enzyme preparation exhibited only one band of 70,000 molecular weight following sodium dodecyl sulfate gel electrophoresis and staining with Coomassie blue. Treatment of the purified oxygenase with [3H] acetylsalicylic acid yielded a radioactive product which co-electrophoresed with the protein of 70,000 molecular weight. Thus, the isolated protein appeared to be the same one which, in crude preparations, selectively binds acetyl groups in association with prostaglandin synthetic activity. Incubation of the purified oxygenase with [1-14C] arachidonic acid in the presence of stannous chloride yielded only 9 alpha, 11 alpha, 15-trihydroxy-prosta-5,13-dienoic acid (PGF2alpha). Without stannous chloride, a mixture of radioactive products was observed which was characteristic of nonenzymic breakdown of PGG2. Thus, the isolated enzyme catalyzed the insertion of both oxygen molecules required for the formation of prostaglandins and thromboxanes from polyunsaturated fatty acid substrates. The aerobic absorption spectrum of the isolated oxygenase showed a faint peak at 412 nm indicative of heme. The iron content indicated that a significant amount of nonheme iron was present. The purified oxygenase was activated by added hemin, which was readily bound to the protein. The subsequently isolated heme-protein complex showed a major absorption peak at 407 nm.     

Comparative functioning of dihydro- and tetrahydropterins in supporting electron transfer, catalysis, and subunit dimerization in inducible nitric oxide synthase

The nitric oxide synthases (NOS) are the only heme-containing enzymes that require tetrahydrobiopterin (BH4) as a cofactor. Previous studies indicate that only the fully reduced (i.e., tetrahydro) form of BH4 can support NO synthesis. Here, we characterize pterin-free inducible NOS (iNOS) and iNOS reconstituted with eight different tetrahydro- or dihydropterins to elucidate how changes in pterin side-chain structure and ring oxidation state regulate iNOS. Seven different enzyme properties that are important for catalysis and are thought to involve pterin were studied. Only two properties were found to depend on pterin oxidation state (i.e., they required fully reduced tetrahydropterins) and were independent of side chain structure: NO synthesis and the ability to increase heme-dependent NADPH oxidation in response to substrates. In contrast, five properties were exclusively dependent on pterin side-chain structure or stereochemistry and were independent of pterin oxidation state: pterin binding affinity, and its ability to shift the heme iron to its high-spin state, stabilize the ferrous heme iron coordination structure, support heme iron reduction, and promote iNOS subunit assembly into a dimer. These results clarify how structural versus redox properties of the pterin impact on its multifaceted role in iNOS function. In addition, the data reveal that during NO synthesis all pterin-dependent steps up to and including heme iron reduction can take place independent of the pterin ring oxidation state, indicating that the requirement for fully reduced pterin occurs at a point in catalysis beyond heme iron reduction.     

Structure of the photoreactive iron center of the nitrile hydratase from Rhodococcus sp. N-771. Evidence of a novel post-translational modification in the cysteine ligand

Nitrile hydratase (NHase) from Rhodococcus sp. N-771 is a photoreactive enzyme that is inactivated by nitrosylation of the non-heme iron center and activated by photodissociation of nitric oxide (NO). To obtain structural information on the iron center, we isolated peptide complexes containing the iron center by proteolysis. When the tryptic digest of the alpha subunit isolated from the inactive form was analyzed by reversed-phase high performance liquid chromatography, the absorbance characteristic of the nitrosylated iron center was observed in the peptide fragment, Asn105-Val-Ile-Val-Cys-Ser-Leu-Cys-Ser-Cys-Thr-Ala-Trp-Pro-Ile-Leu - Gly-Leu-Pro-Pro-Thr-Trp-Tyr-Lys128. The peptide contained 0.79 mol of iron/mol of molecule as well as endogenous NO. Subsequently, by digesting the peptide with thermolysin, carboxypeptidase Y, and leucine aminopeptidase M, we found that the minimum peptide segment required for the nitrosylated iron center is the 11 amino acid residues from alphaIle107 to alphaTrp117. Furthermore, by using mass spectrometry, protein sequence, and amino acid composition analyses, we have shown that the 112th Cys residue of the alpha subunit is post-translationally oxidized to a cysteine-sulfinic acid (Cys-SO2H) in the NHase. These results indicate that the NHase from Rhodococcus sp. N-771 has a novel non-heme iron enzyme containing a cysteine-sulfinic acid in the iron center. Possible ligand residues of the iron center are discussed.     

1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine as a substrate of cytochrome P450 2D6: allosteric effects of NADPH-cytochrome P450 reductase

1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), a neurotoxin that produces Parkinsonism symptoms in man, has been examined as a substrate of recombinant human cytochrome P450 2D6. When cumene hydroperoxide is used as an oxygen and electron donor, a single product is formed, identified as 4-phenyl-1,2,3,6-tetrahydropyridine. The K(m) for formation of this product (130 microM) is in agreement with the dissociation constants for MPTP binding to the enzyme determined by optical and nuclear magnetic resonance (NMR) spectroscopy. When the reaction is carried out with nicotinamide adenine dinucleotide phosphate (reduced) (NADPH) and recombinant human NADPH-cytochrome P450 reductase, a second product, identified as 1-methyl-4-(4'-hydroxyphenyl)-1,2,3,6-tetrahydropyridine, is formed in addition to 4-phenyl-1,2,3,6-tetrahydropyridine. The K(m) values for formation of these two products are 19 microM and 120 microM, respectively. Paramagnetic relaxation experiments have been used to measure distances between the protons of bound MPTP and the heme iron, and these have been used to construct models for the position and orientation of MPTP in the active site. For the cytochrome alone, a single mode of binding was observed, with the N-methyl close to the heme iron in a position appropriate for the observed N-demethylation reaction. In the presence of the reductase, the data were not consistent with a single mode of binding but could be explained by the existence of two alternative orientations of MPTP in the active site. One of these, characterized by a dissociation constant of 150 microM, is essentially identical to that observed in the absence of the reductase. In the second, which has a K(d) of 25 microM, the MPTP is oriented so that the aromatic ring is close to the heme iron, in a position appropriate for p-hydroxylation leading to the formation of the product seen only in the presence of the reductase. In the case of codeine, another substrate for cytochrome P450 2D6, the addition of reductase had no effect on the nature of the product formed, the dissociation constant, or the orientation in the binding site. These observations show that NADPH-cytochrome P450 reductase has an allosteric effect on the active site of cytochrome P450 2D6 that affects the binding of some substrates but not others.     

Steroidogenic electron transport in adrenal cortex mitochondria

The flavoprotein NADPH-adrenodoxin reductase and the iron sulfur protein adrenodoxin function as a short electron transport chain which donates electrons one-at-a-time to adrenal cortex mitochondrial cytochromes P-450. The soluble adrenodoxin acts as a mobile one-electron shuttle, forming a complex first with NADPH-reduced adrenodoxin reductase from which it accepts an electron, then dissociating, and finally reassociating with and donating an electron to the membrane-bound cytochrome P-450 (Fig. 9). Dissociation and reassociation with flavoprotein then allows a second cycle of electron transfers. A complex set of factors govern the sequential protein-protein interactions which comprise this adrenodoxin shuttle mechanism; among these factors, reduction of the iron sulfur center by the flavin weakens the adrenodoxin-adrenodoxin reductase interaction, thus promoting dissociation of this complex to yield free reduced adrenodoxin. Substrate (cholesterol) binding to cytochrome P-450scc both promotes the binding of the free adrenodoxin to the cytochrome, and alters the oxidation-reduction potential of the heme so as to favor reduction by adrenodoxin. The cholesterol binding site on cytochrome P-450scc appears to be in direct communication with the hydrophobic phospholipid milieu in which this substrate is dissolved. Specific effects of both phospholipid headgroups and fatty acyl side-chains regulate the interaction of cholesterol with its binding side. Cardiolipin is an extremely potent positive effector for cholesterol binding, and evidence supports the existence of a specific effector lipid binding site on cytochrome P.450scc to which this phospholipid binds.     

Heme and the endothelium. Effects of nitric oxide on catalytic iron and heme degradation by heme oxygenase

We studied the effects of nitric oxide (NO) on the control of excess cellular heme and release of catalytically active iron. Endothelial cells (ECs) exposed to hemin followed by a NO donor have a ferritin content that is 16% that of cells exposed to hemin alone. Hemin-treated ECs experience a 3.5-fold rise in non-heme, catalytic iron 2 h later, but a hemin rechallenge 20 h later results in only a 24% increase. The addition of a NO donor after the first hemin exposure prevents this adaptive response, presumably due to effects on ferritin synthesis. NO donors were found to reduce iron release from hemin, while hemin accumulated in cells. A NO donor, in a dose-dependent fashion, inhibited heme oxygenase activity, measured by bilirubin production. Using low temperature EPR spectroscopy, heme oxygenase inhibition correlated with nitrosylation of free heme in microsomes. Nitrosylation of cellular heme prevented iron release, for while there was heme oxygenase-dependent release of iron in cells incubated with hemin for 24 h, the addition of a NO donor blocked iron release. This indicates that NO readily nitrosylates intracellular free heme and prevents its degradation by heme oxygenase. Nitrosylation of heme was found to reduce sensitization of cells to oxidative injury.     

Isolation and characterization of a two-subunit cytochrome b-c1 subcomplex from Rhodobacter capsulatus and reconstitution of its ubihydroquinone oxidation (Qo) site with purified Fe-S protein subunit

The presence of a two-subunit cytochrome (cyt) b-c1 subcomplex in chromatophore membranes of Rhodobacter capsulatus mutants lacking the Rieske iron-sulfur (Fe-S) protein has been described previously [Davidson, E., Ohnishi, T., Tokito, M., and Daldal, F. (1992) Biochemistry 31, 3351-3358]. Here, this subcomplex was purified to homogeneity in large quantities, and its properties were characterized. As expected, it contained stoichiometric amounts of cyt b and cyt c1 subunits forming a stable entity devoid of the Fe-S protein subunit. The spectral and thermodynamic properties of its heme groups were largely similar to those of a wild-type bc1 complex, except that those of its cyt bL heme were modified as revealed by EPR spectroscopy. Dark potentiometric titrations indicated that the redox midpoint potential (Em7) values of cytochromes bH, bL, and c1 were very similar to those of a wild-type bc1 complex. The purified b-c1 subcomplex had a nonfunctional ubihydroquinone (UQH2) oxidation (Qo) site, but it contained an intact ubiquinone (UQ) reductase (Qi) site as judged by its ability to bind the Qi inhibitor antimycin A, and by the presence of antimycin A sensitive Qi semiquinone. Interestingly, its Qo site could be readily reconstituted by addition of purified Fe-S protein subunit. Reactivated complex exhibited myxothiazol, stigmatellin, and antimycin A sensitive cyt c reductase activity and an EPR gx signal comparable to that observed with a bc1 complex when the Qo site is partially occupied with UQ/UQH2. However, a mutant derivative of the Fe-S protein subunit lacking its first 43 amino acid residues was unable to reactivate the purified b-c1 subcomplex although it could bind to its Qo site in the presence of stigmatellin. These findings demonstrated for the first time that the amino-terminal membrane-anchoring domain of the Fe-S protein subunit is necessary for UQH2 oxidation even though its carboxyl-terminal domain is sufficient to provide wild-type-like interactions with stigmatellin at the Qo site of the bc1 complex.