Methionine-oxidized horse heart cytochromes c. II. Conformation and heme configuration

The two products from the reaction of horse heart ferricytochrome c with Chloramine-T, the F^III and F^II CT-cytochromes, contain modification of the methionines to methionine sulfoxides, but they are distinct in their physiological functions. Conformational and heme-configurational characterization of the two CT-cytochromes has been carried out by using absorption, circular dichroism, fluorescence, proton magnetic resonance, and resonance Raman spectroscopy. The pH-absorption spectroscopic behavior, thermal stability, and ionization of the phenolic hydroxyls have also been reported. Spectroscopic studies of the heme c fragment, H8, in the presence of dimethylsulfoxide, as a model for CT-cytochrome heme configuration, were also conducted. The ferric and the ferrous CT-cytochromes above pH 7.5 have similar, yet distinct, spectroscopic properties, absorption, CD, resonance Raman, and PMR spectra, typical of low-spin hexacoordinated hemes, but distinct from those of the unmodified protein. The ferric spectrum lacks the 695-nm band, and the reduced spectrum contains an additional inflection at about 400 nm, a feature also observed in the spectra of ferrous H8-DMSO systems. The CD, resonance Raman, and PMR spectra are typical of a cytochrome with a loosened heme crevice and altered coordination configuration. The Methionine-80 proton resonances are absent in the uupfield PMR spectra of both the CT-ferricytochromes. The ferrous spectra, on the other hand, contain all the Met-80 resonances, but with smaller upfield shifts than those of the native protein. Both CT-ferric cytochromes are less stable in the acid region and convert to high-spin forms with a two-step transition and with a distinct set of pK _a values. The overall conformation is nearly identical to that of the native protein, but it is less stable to thermal unfolding. All the factors differentiating the modified preparations from the unmodified protein are more pronunced in the case of F^II, with F^III being the closest to the unmodified form. The two functionally distinct CT-cytochromes are two conformational isomers; conformationally and heme configurationally, they are spectroscopically very similar, yet distinct. Both contain an altered heme iron coordination configuration. The sulfur of Met-80 is repalced by the oxygen of Met-80 sulfoxide of a different configuration, R or S. Both contain a loosened heme crevice and are conformationally less stable than the native protein, F^II CT-cytochrome c being the most deranged.     

Methionine-oxidized horse heart cytochrome c. III. Ascorbate reduction and the methionine-80-sulfur-iron linkage

The ascorbate reduction of the CT-cytochromes—two chemically generated forms of horse heart cytochrome c, F^III and F^II, with both methionines, 80 and 65, as methionine sulfoxides, no iron-sulfur linkage, and potentiometric and physiological oxidoreduction properties distinct from those of the native protein and one another (J. Pande et al., 1987)—has been investigated using a stopped-flow technique. The reaction was monitored at 550 nm, and studies were conducted in 10 mM phosphate +0.17 M NaCl buffer,pH 7.4. Both CT-cytochromes are reduced by triphasic profiles, a faster and an intermediate ascorbate-dependent reaction and a slow, ascorbate-independent process. Both CT-cytochromes contain three molecular forms in slow equilibrium, two reducing directly by reaction with ascorbate and a third through conversion to one of the reducible forms. Like the reaction of the native protein, the ascorbate dependence of both the rapid and the intermediate process is nonlinear, approaching saturation values at high concentrations. The ascorbate profiles of the pseudo-first-order reduction constants are typical of the model for the reduction reaction of the unmodified protein, binding followed by a first-order reduction reaction (Myer et al., 1980; Myer and Kumar, 1984), but with distinct kinetic parameters, the first-order reduction constants and the protein-ascorbate stability constants. It has been concluded that the functional-conformational differences between the two CT-cytochromes are not operational to any significant extent in the reduction reaction with ascorbate. The methionine-80-sulfur-iron linkage of the protein is not a crucial requirement for the ascorbate reduction of the protein. The mechanism of the reaction in the main is also insensitive to the replacement of Met-80-S from heme coordination and/or the associated conformational-oxidoreduction properties of the protein. Of the two aspects of the reaction, the efficiency of the electron-transfer reaction and the stability of the ascorbate dianion-protein complex, the former is dependent on the integrity of the structural-conformational state of the molecule.     

Methionine-oxidized horse heart cytochromec. III. Ascorbate reduction and the methionine-80-sulfur-iron linkage

The ascorbate reduction of the CT-cytochromes—two chemically generated forms of horse heart cytochrome c, F^III and F^II, with both methionines, 80 and 65, as methionine sulfoxides, no iron-sulfur linkage, and potentiometric and physiological oxidoreduction properties distinct from those of the native protein and one another (J. Pande et al., 1987)—has been investigated using a stopped-flow technique. The reaction was monitored at 550 nm, and studies were conducted in 10 mM phosphate +0.17 M NaCl buffer,pH 7.4. Both CT-cytochromes are reduced by triphasic profiles, a faster and an intermediate ascorbate-dependent reaction and a slow, ascorbate-independent process. Both CT-cytochromes contain three molecular forms in slow equilibrium, two reducing directly by reaction with ascorbate and a third through conversion to one of the reducible forms. Like the reaction of the native protein, the ascorbate dependence of both the rapid and the intermediate process is nonlinear, approaching saturation values at high concentrations. The ascorbate profiles of the pseudo-first-order reduction constants are typical of the model for the reduction reaction of the unmodified protein, binding followed by a first-order reduction reaction (Myer et al., 1980; Myer and Kumar, 1984), but with distinct kinetic parameters, the first-order reduction constants and the protein-ascorbate stability constants. It has been concluded that the functional-conformational differences between the two CT-cytochromes are not operational to any significant extent in the reduction reaction with ascorbate. The methionine-80-sulfur-iron linkage of the protein is not a crucial requirement for the ascorbate reduction of the protein. The mechanism of the reaction in the main is also insensitive to the replacement of Met-80-S from heme coordination and/or the associated conformational-oxidoreduction properties of the protein. Of the two aspects of the reaction, the efficiency of the electron-transfer reaction and the stability of the ascorbate dianion-protein complex, the former is dependent on the integrity of the structural-conformational state of the molecule.     

Methionine-oxidized horse heart cytochromes c. I. Reaction with Chloramine-T, products, and their oxidoreduction properties

Spectroscopically, the modification of horse heart ferricytochrome c with N-chloro-4-toluolsul-fonamide (Chloramine-T, CT) occurs through a two-step process, the disruption of the methionine-80 sulfur-iron linkage and a reagent-independent change, an intramolecular rearrangement. Chromatographic purification of the preparation at a 2.5:1 reagent-to-protein ratio, pH 8.0–8.5, yields two major products, the F^II and F^III CT-cytochromes c. Both products contain modification of only the methionines, 80 and 65, to sulfoxides; both are monomeric, reduced by ascorbate, and the ferrous forms are oxidized by molecular oxygen and bind carbon monoxide. The redox potentials of F^II and F^III are 135 and 175±15 mV. The F^III is indistinguishable from the native protein in its binding and the electron donor property toward mammalian cytochrome c oxidase. It also binds nearly as effectively as the native protein to yeast cytochrome c peroxidase, but is a less efficient donor. It is, however, a poor electron acceptor from both mammalian cytochrome c reductase and chicken liver sulfite oxidase. F^II lacks cytochrome c oxidase activity and is also a poorer substrate for the other three enzymes. Both the derivatives are consistently better electron donors than acceptors. It is concluded that the binding of cytochrome c to cytochrome c oxidase and to cytochrome c peroxidase does not require the integrity of the methionine-80 sulfur linkage and that the complexation process has a finite degree of freedom with regard to the state of the heme crevice opening. The alterations of the oxidoreduction function have been analyzed in light of both prevailing models of cytochrome c function, the two-site model (one site for oxidizing and the other for reducing enzymes) and the single-site model (the same site for the oxidizing and reducing enzymes). These observations can be accommodated by either model, given the latitude that the binding domains for the oxidizing and the reducing enzymes have finite overlapping and nonoverlapping regions.To whom all correspondence related to the functional studies with cytochrome c peroxidase and sulfite oxidase is to be directed.     

Methionine-oxidized horse heart cytochromes c. I. Reaction with Chloramine-T,products, and their oxidoreduction properties

Spectroscopically, the modification of horse heart ferricytochrome c with N-chloro-4-toluolsul-fonamide (Chloramine-T, CT) occurs through a two-step process, the disruption of the methionine-80 sulfur-iron linkage and a reagent-independent change, an intramolecular rearrangement. Chromatographic purification of the preparation at a 2.5:1 reagent-to-protein ratio, pH 8.0–8.5, yields two major products, the F^II and F^III CT-cytochromes c. Both products contain modification of only the methionines, 80 and 65, to sulfoxides; both are monomeric, reduced by ascorbate, and the ferrous forms are oxidized by molecular oxygen and bind carbon monoxide. The redox potentials of F^II and F^III are 135 and 175±15 mV. The F^III is indistinguishable from the native protein in its binding and the electron donor property toward mammalian cytochrome c oxidase. It also binds nearly as effectively as the native protein to yeast cytochrome c peroxidase, but is a less efficient donor. It is, however, a poor electron acceptor from both mammalian cytochrome c reductase and chicken liver sulfite oxidase. F^II lacks cytochrome c oxidase activity and is also a poorer substrate for the other three enzymes. Both the derivatives are consistently better electron donors than acceptors. It is concluded that the binding of cytochrome c to cytochrome c oxidase and to cytochrome c peroxidase does not require the integrity of the methionine-80 sulfur linkage and that the complexation process has a finite degree of freedom with regard to the state of the heme crevice opening. The alterations of the oxidoreduction function have been analyzed in light of both prevailing models of cytochrome c function, the two-site model (one site for oxidizing and the other for reducing enzymes) and the single-site model (the same site for the oxidizing and reducing enzymes). These observations can be accommodated by either model, given the latitude that the binding domains for the oxidizing and the reducing enzymes have finite overlapping and nonoverlapping regions.     

Horse heart ferricytochrome c: conformation and heme configuration of high ionic strength acidic forms.

The absorption, circular dichroism, and resonance Raman spectra of horse heart ferricytochromec in the presence of 0.2 M KCl, 0.1 M NaClO₄, and 0.2 M KNO₃, in thepH region 7 to 0.5, have been investigated to determine the nature and the course of the processes involved. As in the absence of salts (Myer, Y., and Saturno, A. F. (1990)J. Protein Chem.,9, 379–387), the change from neutral to low acidicpH's in the presence of salts is a three-step process: state III _s state III _s,a state II _s state I _s , withpK _a 's of 3.5±0.2, 2.2±0.2, and 1.1±0.2, and with two, one, and one number of protons, respectively. The addition of salts at neutralpH's has little or no effect on the protein conformation and the heme-iron configuration (i.e., they remain the same, low-spin hexacoordinated heme iron with a Met-80-Fe-His-18 axial coordination), but such addition does cause a slight tightening of the heme crevice and the enlargement of the porphyrin core. State III _s,a is a folded state with about the same degree of folding and with a similar spin state and coordination configuration of iron, but the heme crevice is loosened and the porphyrin core is smaller. Both states II _s and I _s are also essentially folded forms, but with a smaller degree of protein secondary structure. State II _s has a high-spin hexacoordinated heme iron with a water molecule and a protonated and/or hydrogen-bonded imidazole of his-18 as the two axial ligates; and state I _s has a high-spin pentacoordinated heme iron, which is about 0.49 Å out of the porphyrin plane, with a protonated and/or hydrogen-bonded imidazole nitrogen as the only axial ligate. The addition of anions causes the stabilization of the protein secondary structures and the state III _a state II transition. The mode of effectiveness of anions appears to be nonspecific (i.e., because of electrostatic shielding and/or disruption of salt bridges).     

Roles of Arg-97 and Phe-113 in regulation of distal ligand binding to heme in the sensor domain of Ec DOS protein. Resonance Raman and mutation study

The direct oxygen sensor protein isolated from Escherichia coli (Ec DOS) is a heme-based signal transducer protein responsible for phosphodiesterase (PDE) activity. Binding of O(2), CO, or NO to a reduced heme significantly enhances the PDE activity toward 3',5'-cyclic diguanylic acid. We report stationary and time-resolved resonance Raman spectra of the wild-type and several mutants (Glu-93 --> Ile, Met-95 --> Ala, Arg-97 --> Ile, Arg-97 --> Ala, Arg-97 --> Glu, Phe-113 --> Leu, and Phe-113 --> Thr) of the heme-containing PAS domain of Ec DOS. For the CO- and NO-bound forms, both the hydrogen-bonded and non-hydrogen-bonded conformations were found, and in the former Arg-97 forms a hydrogen bond with the heme-bound external ligand. The resonance Raman results revealed significant interactions of Arg-97 and Phe-113 with a ligand bound to the sixth coordination site of the heme and profound structural changes in the heme propionates upon dissociation of CO. Mutation of Phe-113 perturbed the PDE activities, and the mutation of Arg-97 and Phe-113 significantly influenced the transient binding of Met-95 to the heme upon photodissociation of CO. This suggests that the electrostatic interaction of Arg-97 and steric interaction of Phe-113 are crucial for regulating the competitive recombination of Met-95 and CO to the heme. On the basis of these results, we propose a model for the role of the heme propionates in communicating the heme structural changes to the protein moiety.     

Spectroscopic characterization of (57)Fe-enriched cytochrome c

Investigation of the heme iron dynamics in cytochrome c with Mössbauer spectroscopy and especially nuclear resonance vibrational spectroscopy requires the replacement of the natural abundant heme iron with the ⁵⁷Fe isotope. For demetallization, we use a safer and milder ferrous sulfate–hydrochloric acid method in addition to the harsher commonly used hydrofluoric acid-based procedure. The structural integrity of the ⁵⁷Fe-reconstituted protein in both oxidation states is confirmed from absorption spectra and a detailed analysis of the rich resonance Raman spectra. These results reinforce the application of metal-substituted heme c proteins as reliable models for the native proteins.     

Effect of covalent links on the structure, spectra, and redox properties of myeloperoxidase--a density functional study

The enzyme myeloperoxidase shows several unusual properties compared to other peroxidases, e.g. a red-shifted absorption spectrum and a peroxidase activity towards chloride. It has been suggested that this is caused by the unusual covalent links between the heme group and the surrounding protein, but whether it is caused by the two ester links to Glu-242 and Asp-94 or the sulfonium ion linkage to Met-243 is unclear. To investigate these suggestions, we have used density functional theory to study the structure, spectra, and reduction potential of 25 models of myeloperoxidase in the reduced (Fe^II) and oxidized (Fe^III) states, as well as in the compound I (formally Fe^VO) and II (Fe^IVO or Fe^IVOH) states, using appropriate models of the linkages to the Asp, Glu, and Met residues (including the back-bone connection between Glu-242 and Met-243) in varying combinations. The calculated spectral shifts indicate that both the ester and sulfonium linkages play a role in the spectral shift. On the other hand, the sulfonium linkage seems to be mainly responsible for the high positive reduction potential for the both ferric/ferrous and compound I/II couples of myeloperoxidase.     

State of heme in heme c systems: Cytochrome c and heme c models

Polarized resonance Raman spectra of horse heart ferricytochrome c as a function of pH in the range 1.0–12, in the presence of the extrinsic ligands imidazole, cyanide, and azide, and in 4 M urea, are reported, as are resonance Raman spectra of heme undecapeptide in the presence of imidazole, pH 6.8 and pH 2.0, and with cyanide at pH 6.8. The range of investigation is 140–1700 cm^?1, using the 5145-, 4880-, and 4579-Å excitations. The spectra have been analyzed in terms of complexity, sensitivity, and the conformation-heme energetics of the systems. The state of heme in various forms is analyzed with regard to heme energetics, core size, nature of planarity, and coordination configuration. All low-spin forms of heme c systems, cytochrome c, and heme models are concluded to be hexacoordinated, in-plane heme iron systems. The effect of the location of the heme in the protein environment is found to be a slight expansion of the porphyrin core, ～0.01 Å, while the covalent linkage of heme to protein and a mixed nature of axial coordination configuration seem to have little effect on the energetics of the heme group. Complex formation with extrinsic ligand, imidazole, cyanide, or azide, results in a slight contraction of the heme core. The formation of cytochrome c form IV, the alkaline form, is shown to follow a process with apK _a of about 8.4, and similarly, acidic form II is created following the prior formation of an intermediate form with apK _a of about 3.6. The precursor to form IV is interpreted as containing perturbation of the pyrrol rings, whereas the precursor to the acidic form seems to reflect alteration of the energetics of the C_αC_{m α} structures of the heme group. The acidic form of heme undecapeptide is a hexacoordinated high-spin heme with an estimated displacement of 0.25 Å from the heme plane. The pH 2 form of cytochrome c is also a hexacoordinated high-spin form with two weak axial ligands, but iron is in the plane of the porphyrin ring.     

Chemical modification of methionine residues of the phosphatidylcholine transfer protein from bovine liver. A spin-label study

The role of methionine residues in the interaction of the phosphatidylcholine transfer protein from bovine liver with phospholipid vesicles was investigated by specific modification of these residues with iodoacetamide. The modified protein was digested with cyanogen bromide in order to determine which methionine residues had become resistant to this cleavage. Automated Edman degradation on the digest indicated that after 72 h of reaction, Met-1 was modified for 80%, Met-73 for 50%, Met-109 for 20%, whilst Met-173 and Met-203 were found to be unmodified. This distinct modification did not result in any loss of phosphatidylcholine transfer activity. The interaction of the phosphatidylcholine transfer protein with phospholipid vesicles was investigated by making use of electron spin resonance spectroscopy. The interaction of unmodified protein with vesicles composed of phosphatidylcholine/phosphatidic acid/spin-labeled phosphatidylethanolamine (79:16:5, mol%) or composed of phosphatidylserine/spin-labeled phosphatidylethanolamine (95:5, mol%), gave an increase of about 50% in the rotation correlation time. A similar increase was observed with the modified protein. This interaction was further investigated by labeling Met-1 and Met-73 in the transfer protein with iodoacetamidoproxyl spin-label. Spin-labeling did not inactivate the transfer protein. In addition, the electron spin resonance spectra of the spin-labeled protein were not affected upon addition of vesicles composed of phosphatidylcholine/phosphatidic acid (80:20, mol%). These experiments strongly suggest that Met-1 and Met-73 are not part of the site that interacts with the membrane.     

Ligand dynamics and early signaling events in the heme domain of the sensor protein Dos from Escherichia coli

In the heme-based sensor Dos from Escherichia coli, the ferrous heme is coordinated by His-77 and Met-95. The latter residue is replaced upon oxygen binding or oxidation of the heme. Here we investigate the early signaling processes upon dissociation of the distal ligand using ultrafast spectroscopy and site-directed mutagenesis. Geminate CO rebinding to the heme domain DosH appears insensitive to replacement of Met-95, in agreement with the notion that this residue is oriented out of the heme pocket in the presence of external ligands. A uniquely slow 35-ps phase in rebinding of the flexible methionine side chain after dissociation from ferrous DosH is completely abolished in rebinding of the more rigid histidine side chain in the M95H mutant protein, where only the 7-ps phase, common to all 6-coordinate heme proteins, is observed. Temperature-dependence studies indicate that all rebinding of internal and external ligands is essentially barrierless, but that CfigsO escape from the heme pocket is an activated process. Solvent viscosity studies combined with molecular dynamics simulations show that there are two configurations in the ferrous 6-coordinate protein, involving two isomers of the Met-95 side chain, of which the structural changes extend to the solvent-exposed backbone, which is part of the flexible FG loop. One of these configurations has considerable motional freedom in the Met-95-dissociated state. We suggest that this configuration corresponds to an early signaling intermediate state, is responsible for the slow rebinding, and allows small ligands in the protein to efficiently compete for binding with the heme.     

Spectroscopic and kinetic properties of an oxygen-binding heme protein from Chromatium vinosum

Resonance Raman and electron paramagnetic resonance spectroscopy have been utilized to identify histidine as an axial heme ligand in a high spin, heme c-containing protein isolated from the photosynthetic purple sulfur bacterium Chromatium vinosum. Resonance Raman spectroscopy has also been used to characterize the CO adduct of the C. vinosum hemoprotein. Resonance Raman spectra of the heme site obtained within 10 ns of CO photolysis from the ferrous hemoprotein are virtually identical to those of the unligated protein, indicating that there is little or no rearrangement of the heme pocket in response to ligand photolysis. The equilibrium constant for CO binding to the ferrous hemeprotein was measured to be 1.7 X 10(-5) M-1 and the CO association rate constant determined to be 5.4 X 10(3) M-1 S-1. The quantum efficiency for photodissociation of the hemoprotein X CO complex was greater than or equal to 0.9.     

Quantitative conformational analysis of cytochromec bound to phospholipid vesicles studied by resonance Raman spectroscopy

Resonance Raman spectra have been recorded from ferri-cytochromec bound to phospholipid vesicles composed of dimyristoyl phosphatidylglycerol (DMPG), dioleoyl phosphatidylglycerol (DOPG) or dioleoyl phosphatidylglycerol-dioleoyl phasphatidylcholine (DOPG-OPC) (70 : 30 mole/mole). Lipid binding induces very significant conformational changes in the protein molecule. The resonance Raman spectra differ in their content of bands originating from two different conformational species, I and II, of the protein, and from two different spin and coordination states of the heme in conformation II. Data of sufficiently high precision were obtained that the spectra of the individual species could be quantitated by a constraint interative fitting routine using single Lorentzian profiles. In the high frequency, or marker band region (1200 to 1700 cm⁻¹), the frequencies, half widths and relative intensities of the individual bands could be estimated from previous surface enhanced resonance Raman measurements on cytochromec adsorbed on a silver electrode. These were then further optimized to yield both the spectral parameters and relative contents of the different species. In the low frequency, or finger-print, region (200 to 800 cm⁻¹), the spectral parameters of the individual species were obtained from difference spectra derived by sequential subtraction between the spectra of ferri-cytochromec in the three different lipid systems, using the relative proportions of the species derived from the marker band region. These parameters were then subsequently refined by iterative optimization. The optimized spectral parameters in both frequency regions for the six-coordinated low spin states I and II, and for the five-coordinated high spin state II are presented. The proportion of state II, in which hence the heme crevice assumes an open structure, and of the five-coordinated high spin configuration, is found to increase on binding ferri cytochromec to negatively charged lipid vesicles. The extent of this conformational change increases in the order: DOPG-DOPC<DOPG<DMPG, with a parallel decrease of the proportion of the conformational state I, whose structure is similar to that of the uncomplexed ferri-cytochrome c in solution. Similar conformational changes are found for ferro-cytochromec compared to those obtained with the oxidized species on binding to lipids. The present work is essential for studies which seek to analyze, in any detailed fashion, the conformational transitions in the heme protein which take place in response to changes in the lipid environment.     

Identification of heme axial ligands of cytochrome c' from Alcaligenes sp. N.C.I.B. 11015

The spectral properties of both ferric and ferrous cytochromes c' from Alcaligenes sp. N.C.I.B. 11015 are reported. The EPR spectra at 77 K and the electronic, resonance Raman, CD and MCD spectra at room temperature have been compared with those of the other cytochromes c' and various hemoproteins. In the ferrous form, all the spectral results at physiological pH strongly indicated that the heme iron(II) is in a high-spin state. In the ferric form, the EPR and electronic absorption spectra were markedly dependent upon pH. EPR and electronic spectral results suggested that the ground state of heme iron(III) at physiological pH consists of a quantum mechanical admixture of an intermediate-spin and a high-spin state. Under highly alkaline conditions, identification of the axial ligands of heme iron(III) was attempted by crystal field analysis of the low-spin EPR g values. Upon the addition of sodium dodecyl sulfate to ferric and ferrous cytochrome c', the low-spin type spectra were induced. The heme environment of this low-spin species is also discussed.     

An unusual hemoprotein capable of reversible binding of nitric oxide from the gram-positive Bacillus halodenitrificans

A green protein from the soluble extract of anaerobically grown Bacillus halodenitrificans cells was purified and determined by non-denaturing procedures or SDS-PAGE to have a molecular mass of 64 kDa. The pyridine hemochromogen was shown to be that of a b-type cytochrome prosthetic group that was soluble in ether. The protein contained 6.2mol protoheme per mol protein^-1. Photoreduction of the native protein yielded a product with an electronic absorption spectrum retaining the 559 nm maximum and the 424-nm Soret band displayed in the dithionite-reduced sample. Incubation of a reduced sample in the presence of air failed to return it to the original oxidation state. Electronic spin was not affected by pH. The reduced but not the oxidized form of the cytochrome bound cyanide, carbon monoxide, and nitric oxide, providing spectra resembling those of cytochromes c from several sources. Addition of nitroprusside to the reduced protein yielded a spectrum similar to that of the NO reacted protein. Nitric oxide failed to reduce the green protein. The position of the Soret band in the spectrum of the nitric oxide derivative of the green protein suggested a fifth-coordinate nitrosylheme structure. EPR studies provided g values with the triplet spectral pattern consistent with a five-coordinate ferrous nitrosyl heme. Flushing of the NO-derivative with argon and overnight exposure to air returned the nitrosylheme to the ferric form, and EPR values confirmed the reversion. All these spectral characterizations are strikingly similar to those of soluble guanylate cyclase, including the observation that NO was reversibly bound to the protein. EPR spectra of whole cells also displayed the hyperfine lines typical of a nitrosyl-ferrous heme, accentuated when dithionite was added. In the absence of a definitive physiological role because of its unusual properties, the green protein was named a nitric oxide-binding protein.Abbreviations PMS Phenazine methosulfate - PMSF Phenylmethyl sulfonyl fluoride - SOD Super oxide dismutase - EPR Electron paramagnetic resonance - GP Green protein Department of Biological Sciences, Oakland Univeristy, Rochester, MI 48309-4401     

Resonance Raman spectral isolation of the a and a3 chromophores in cytochrome oxidase.

Resonance Raman spectra of reduced CO-bound cytochrome oxidase obtained at two different excitation frequencies (441.6 and 413.1 nm) are compared with the spectra of the fully reduced enzyme. In the spectra of the CO-bound complex only the cytochrome a modes are strongly enhanced with 441.6 nm excitation and only the modes of the CO-bound cytochrome a3 heme are strongly enhanced with 413.1-nm excitation. In the fully reduced complex with both excitation frequencies, modes of both cytochrome a and a3 are enhanced. By subtraction we are able to uncover the complete spectrum of the fully reduced ligand-free cytochrome a3 heme. Thus, we report the discrete resonance Raman spectra of cytochromes a2+, a2+3, and a2+3 (CO). The spectra of fully reduced cytochrome a and ligand-free cytochrome a3 are very different especially in the low frequency region. Binding CO to ferrous cytochrome a3 results in electronic structure changes in the heme analogous to those in hemoglobin and myoglobin, from which we conclude that there is nothing electronically unique in the ferrous cytochrome a3 heme to account for its catalytic properties.     

On the structure of the iron-sulfur complex in the two-iron ferredoxins

Recent spectroscopic and magnetic susceptibility studies of the iron center in the two-iron ferredoxins provide criteria which any model for the iron-sulfur complex in these proteins must satisfy. These criteria are most stringent for parsley and spinach ferredoxin: the reduced proteins contain a high-spin ferric atom antiferromagnetically exchange-coupled (presumably via sulfide bridging ligands) to a high-spin ferrous atom. In the oxidized proteins the iron atoms are antiferromagnetically spin-coupled, high-spin ferric atoms. Arguments are given to substantiate the claim that the ferrous atom in the reduced protein is ligated by four sulfur atoms in a distorted tetrahedral configuration: two are the bridging sulfides, two are cysteinyl sulfurs. A treatment of proton contact shifts based upon the above model is pertinent to proton magnetic resonance data already available and provides a means to identify directly the ligands at both iron atoms via further PMR experiments.     

Resonance Raman investigation of a soluble cytochrome c552 from alkaliphilic Bacillus firmus RAB

The environment of the heme site of a low-potential soluble cytochrome (c552) from alkaliphilic Bacillus firmus RAB has been characterized with resonance Raman scattering and compared to that of horse heart cytochrome c. The Raman data indicate that vibrational bands sensitive to the axial ligation of the heme, as well as modes sensitive to the heme peripheral environment in cytochrome c552, are distinct from those of horse heart cytochrome c. The spectra of cytochrome c552 display resonance Raman modes indicative of a methionine as the sixth ligand in the oxidized form, while the reduced form appears to contain a nitrogenous-based sixth ligand. In addition, Q-band excitation reveals differences among vibrational modes in cytochrome c552 that are sensitive to the amino acid environment surrounding the heme.     

Spectroscopic characterization of mononitrosyl complexes in heme--nonheme diiron centers within the myoglobin scaffold (Fe(B)Mbs): relevance to denitrifying NO reductase

Denitrifying NO reductases are evolutionarily related to the superfamily of heme--copper terminal oxidases. These transmembrane protein complexes utilize a heme-nonheme diiron center to reduce two NO molecules to N(2)O. To understand this reaction, the diiron site has been modeled using sperm whale myoglobin as a scaffold and mutating distal residues Leu-29 and Phe-43 to histidines and Val-68 to a glutamic acid to create a nonheme Fe(B) site. The impact of incorporation of metal ions at this engineered site on the reaction of the ferrous heme with one NO was examined by UV-vis absorption, EPR, resonance Raman, and FTIR spectroscopies. UV--vis absorption and resonance Raman spectra demonstrate that the first NO molecule binds to the ferrous heme, but while the apoproteins and Cu(I)- or Zn(II)-loaded proteins show characteristic EPR signatures of S = 1/2 six-coordinate heme {FeNO}(7) species that can be observed at liquid nitrogen temperature, the Fe(II)-loaded proteins are EPR silent at ≥30 K. Vibrational modes from the heme [Fe-N-O] unit are identified in the RR and FTIR spectra using (15)NO and (15)N(18)O. The apo and Cu(I)-bound proteins exhibit ν(FeNO) and ν(NO) that are only marginally distinct from those reported for native myoglobin. However, binding of Fe(II) at the Fe(B) site shifts the heme ν(FeNO) by 17 cm(-1) and the ν(NO) by -50 cm(-1) to 1549 cm(-1). This low ν(NO) is without precedent for a six-coordinate heme {FeNO}(7) species and suggests that the NO group adopts a strong nitroxyl character stabilized by electrostatic interaction with the nearby nonheme Fe(II). Detection of a similarly low ν(NO) in the Zn(II)-loaded protein supports this interpretation.