Optimal NF kappa B mediated transcriptional responses in Jurkat T cells exposed to oxidative stress are dependent on intracellular glutathione and costimulatory signals

The spectral and electrochemical parameters, as well as the orientations of the heme plane with respect to the membrane plane, of the c-type hemes present in membrane fragments from Heliobacillus mobilis were characterised by optical and EPR spectroscopy. Cytochrome C53, was thereby shown to represent at least four and possibly five heme species with the following characteristics: Em = -60 mV +/- 10 mV, g, = 2.92, 60 degrees; Em = +90 mV +/- 10 mV, g, = 2.92, 90 degrees; Em = +120 mV +/- 20 mV, g, = 3.03; and Em = +170 mV +/- 20 mV, g, = 3.03. The latter component may correspond to two hemes with redox midpoint potentials of Em = +160 mV +/- 20 mV and Em = +180 mV +/- 20 mV (all Em values at pH 7.0). For the heme species having g, peaks at g approximately 3.03, determination of individual orientations was precluded due to the superposition of several differently oriented hemes. About one copy of each heme was found to be present per photosynthetic reaction centre, with the exception of the +120 mV component for which a stoichiometry of 2 hemes/reaction centre was obtained. The heme proteins were detergent-solubilised and partially purified. Three c-type cytochromes that migrated with apparent molecular masses of 18, 29 and 50 kDa were detected on SDS/PAGE. Optical redox titrations at pH 7.0 showed redox midpoint potentials of +160 mV +/- 10 mV for the 18-kDa cytochrome, and -60 mV +/- 10 mV, with possible contributions around +160 mV, for the 50-kDa cytochrome. A tentative attribution of heme species observed in membranes to the isolated heme proteins is presented. The results obtained on H. mobilis are compared with those reported for green sulphur bacteria.     

A single mutation in the heme 4 environment of Desulfovibrio desulfuricans Norway cytochrome c3 (Mr 26,000) greatly affects the molecule reactivity

The gene encoding Desulfovibrio desulfuricans Norway cytochrome c3 (Mr 26,000), a dimeric octaheme cytochrome belonging to the polyheme cytochrome c3 superfamily, has been cloned and successfully expressed in another sulfate reducing bacteria, D. desulfuricans G201. The gene, named cycD, is monocistronic and encodes a cytochrome precursor of 135 amino acids with an extension at the NH2 terminus of 24 amino acids. This extension acts as a signal sequence which allows export across the cytoplasmic membrane into the periplasmic space. Tyrosine 73, which is in a close contact with the histidine sixth axial ligand to the heme 4 iron atom, has been replaced by a glutamate residue using site-directed mutagenesis. The cytochrome mutant when expressed in D. desulfuricans G201, is correctly folded and matured. A global increase of the oxidoreduction potentials of about 50 mV is measured for the Y73E cytochrome. The mutation also has a strong influence on the interaction of the cytochrome with its redox partner, the hydrogenase. This suggests, like the tetraheme cytochrome c3 (Mr 13, 000), heme 4 is the interactive heme in the cytochrome-hydrogenase complex and that alteration of the heme 4 environment can greatly affect the electron transfer reaction with its redox partner.     

Effects of temperature and deltaGo on electron transfer from cytochrome c2 to the photosynthetic reaction center of the purple bacterium Rhodobacter sphaeroides

The kinetics of electron transfer from cytochrome c2 to the primary donor (P) of the reaction center from the photosynthetic purple bacterium Rhodobacter sphaeroides have been investigated by time-resolved absorption spectroscopy. Rereduction of P+ induced by a laser pulse has been measured at temperatures from 300 K to 220 K in a series of specifically mutated reaction centers characterized by altered midpoint redox potentials of P+/P varying from 410 mV to 765 mV (as compared to 505 mV for wild type). Rate constants for first-order electron donation within preformed reaction center-cytochrome c2 complexes and for the bimolecular oxidation of free cytochrome c2 have been obtained by multiexponential deconvolution of the kinetics. At all temperatures the rate of the fastest intracomplex electron transfer increases by more than two orders of magnitude as the driving force -deltaGo is varied over a range of 350 meV. The temperature and deltaGo dependences of the rate constant fit the Marcus equation well. Global analysis yields a reorganization energy lambda = 0.96 +/- 0.07 eV and a set of electronic matrix elements, specific for each mutant, ranging from 1.2 10(-4) eV to 2.5 10(-4) eV. Analysis in terms of the Jortner equation indicates that the best fit is obtained in the classical limit and restricts the range of coupled vibrational modes to frequencies lower than approximately 200 cm(-1). An additional slower kinetic component of P+ reduction, attributed to electron transfer from cyt c2 docked in a nonoptimal configuration of the complex, displays a Marcus type dependence of the rate constant upon deltaGo, characterized by a similar value of lambda (0.8 +/- 0.1 eV) and by an average electronic matrix element smaller by more than one order of magnitude. In all of the mutants, as the temperature is decreased below 260 K, both intracomplex reactions are abruptly inhibited, their rate being negligible at 220 K. The free energy dependence of the second-order rate constant for oxidation of cyt c2 in solution suggests that the collisional reaction is partially diffusion controlled, reaching the diffusion limit at exothermicities between 150 and 250 meV over the temperature range investigated.     

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.     

Low-temperature electron transfer from cytochrome to the special pair in Rhodopseudomonas viridis: role of the L162 residue

Electron transfer from the tetraheme cytochrome c to the special pair of bacteriochlorophylls (P) has been studied by flash absorption spectroscopy in reaction centers isolated from seven strains of the photosynthetic purple bacterium Rhodopseudomonas viridis, where the residue L162, located between the proximal heme c-559 and P, is Y (wild type), F, W, G, M, T, or L. Measurements were performed between 294 K and 8 K, under redox conditions in which the two high-potential hemes of the cytochrome were chemically reduced. At room temperature, the kinetics of P+ reduction include two phases in all of the strains: a dominant very fast phase (VF), and a minor fast phase (F). The VF phase has the following t(1/2): 90 ns (M), 130 ns (W), 135 ns (F), 189 ns (Y; wild type), 200 ns (G), 390 ns (L), and 430 ns (T). These data show that electron transfer is fast whatever the nature of the amino acid at position L162. The amplitudes of both phases decrease suddenly around 200 K in Y, F, and W. The effect of temperature on the extent of fast phases is different in mutants G, M, L, and T, in which electron transfer from c-559 to P+ takes place at cryogenic temperatures in a substantial fraction of the reaction centers (T, 48%; G, 38%; L, 23%, at 40 K; and M, 28%, at 60 K), producing a stable charge separated state. In these nonaromatic mutants the rate of VF electron transfer from cytochrome to P+ is nearly temperature-independent between 294 K and 8 K, remaining very fast at very low temperatures (123 ns at 60 K for M; 251 ns at 40 K for L; 190 ns at 8 K for G, and 458 ns at 8 K for T). In all cases, a decrease in amplitudes of the fast phases is paralleled by an increase in very slow reduction of P+, presumably by back-reaction with Q(A)-. The significance of these results is discussed in relation to electron transfer theories and to freezing at low temperatures of cytochrome structural reorganization.     

In vivo induction of sister chromatid exchange in mouse bone marrow following oral exposure to commercial formulations of alpha-cyano pyrethroids

Electron transfer from the proximal heme c-559 to the primary donor P has been studied in reaction centers of the photosynthetic bacterium Rhodopseudomonas viridis in which the tyrosine residue L162 was replaced by threonine. In the wild type, when the two high-potential hemes of the tetraheme cytochrome are reduced before flash excitation, a rapid electron transfer (t1/2 = 190 ns) observed at ambient temperature disappears below 190 K. In the mutant, the reaction is partly maintained down to 8 K, leading to irreversible charge separation. The reaction rate is nearly temperature-independent between 294 K and 8 K (t1/2 approximately 450 ns). The different behavior of wild type and mutant reaction centers is attributed to differences in a network of water molecules, the freezing of which may block structural reorganizations associated with cytochrome oxidation, in the wild type but not in the mutant.     

Hydrogen-bond interactions of the primary donor of the photosynthetic purple sulfur bacterium Chromatium tepidum

We have used near-infrared Fourier transform (pre)resonance Raman spectroscopy to determine the protein interactions with the bacteriochlorophyll (BChl) dimer constituting the primary electron donor, P, in the reaction center (RC) from the thermophilic purple sulfur bacterium Chromatium tepidum. In addition, we report the alignment of partial sequences of the L and M protein subunits of C. tepidum RCs in the vicinity of the primary donor with those of Rhodobacter sphaeroides and Rhodopseudomonas viridis. Taken together, these results enable us to propose the hydrogen-bonding pattern and the H-bond donors to the conjugated carbonyl groups of P. Selective excitation (1064-nm laser radiation) of the FT (pre)-resonance Raman spectra of P in its neutral (P degree) and oxidized (P degree +) states were obtained via their electronic absorption bands at 876 and 1240 nm, respectively. The P degree spectrum exhibits vibrational frequencies at 1608, 1616, 1633, and 1697 cm-1 which bleach upon P oxidation. The P degree + spectrum exhibits new bands at 1600, 1639, and 1719 cm-1. The 1608-cm-1 band, which downshifts to 1600 cm-1 upon oxidation, is assigned to a CaCm methine bridge stretching mode of the P dimer, indicating that each BChl molecule possesses a single axial ligand (His L181 and His M201, from the sequence alignment). The 1616- and 1633-cm-1 bands correspond to two H-bonded pi-conjugated acetyl carbonyl groups of each BChl molecule. with different H-bond strengths: the 1616-cm-1 band is assigned to the PL C2 acetyl group which is H-bonded to a histidine residue (His L176), while the 1633-cm-1 band is assigned to the PM C2 acetyl carbonyl, H-bonded to a tyrosine residue (Tyr M196). Both PL and PM C9 keto carbonyls are free from interactions and vibrate at the same frequency (1697 cm-1). Thus, the H-bond pattern of the primary donor of C. tepidum differs from that of Rb. sphaeroides in the extra H-bond to the PM C2 acetyl carbonyl group; that of PL is H-bonded to a histidine residue in both primary donors (His L168 in Rb. sphaeroides and His L176 in C. tepidum). The P degree/P degree + redox midpoint potentials were measured to be +497 and +526 mV for isolated C. tepidum RCs with and without the associated tetraheme cytochrome c subunit, respectively, and +502 mV for intracytoplasmic membranes. The positive charge localization was estimated to be 69% in favor of PL, indicating a more delocalized situation over the primary donor of C. tepidum than that of Rb. sphaeroides (estimated to be 80% on PL). These differences in physicochemical properties are discussed with respect to the proposed structural model for the microenvironment of the primary donor of C. tepidum.     

Temperature-jump and potentiometric studies on recombinant wild type and Y143F and Y254F mutants of Saccharomyces cerevisiae flavocytochrome b2: role of the driving force in intramolecular electron transfer kinetics

The kinetics of intramolecular electron transfer between flavin and heme in Saccharomyces cerevisiae flavocytochrome b2 were investigated by performing potentiometric titrations and temperature-jump experiments on the recombinant wild type and Y143F and Y254F mutants. The midpoint potential of heme was determined by monitoring redox titrations spectrophotometrically, and that of semiquinone flavin/reduced flavin (Fsq/Fred) and oxidized flavin (Fox)/Fsq couples by electron paramagnetic resonance experiments at room temperature. The effects of pyruvate on the kinetic and thermodynamic parameters were also investigated. At room temperature, pH 7.0 and I = 0.1 M, the redox potential of the Fsq/Fred, Fox/Fsq, and oxidized heme/reduced heme (Hox/Hred) couples were -135, -45, and -3 mV, respectively, in the wild-type form. Although neither the mutations nor excess pyruvate did appreciably modify the potential of the heme or that of the Fsq/Fred couple, they led to variable positive shifts in the potential of the Fox/Fsq couple, thus modulating the driving force that characterizes the reduction of heme by the semiquinone in the -42 to +88 mV range. The relaxation rates measured at 16 degreesC in temperature-jump experiments were independent of the protein concentrations, with absorbance changes corresponding to the reduction of the heme. Two relaxation processes were clearly resolved in wild-type flavocytochrome b2 (1/tau1 = 1500 s-1, 1/tau2 = 200 +/- 50 s-1) and were assigned to the reactions whereby the heme is reduced by Fred and Fsq, respectively. The rate of the latter reaction was determined in the whole series of proteins. Its variation as a function of the driving force is well described by the expression obtained from electron-transfer theories, which provides evidence that the intramolecular electron transfer is not controlled by the dynamics of the protein.     

Evidence for coupled electron and proton transfer in the [8Fe-7S] cluster of nitrogenase

Substrate reduction by nitrogenase requires electron transfer from a [4Fe-4S] cluster in the iron (Fe) protein component to an FeMo cofactor in the molybdenum-iron (MoFe) protein component in a reaction that is coupled to MgATP hydrolysis and component protein association and dissociation. An [8Fe-7S] (or P-) cluster in the MoFe protein has been proposed as an intermediate electron-transfer site, although how this cluster functions in electron-transfer remains unclear. In the present work, it is demonstrated that one redox couple of the P-cluster (P2+/1+) undergoes coupled electron and proton transfer, whereas a more reduced couple (P1+/N) does not involve a coupled proton transfer. Redox titrations of the MoFe protein P-cluster were performed, and the midpoint potential of the P2+/1+ couple (Em2) was found to be pH dependent, ranging from -224 mV at pH 6.0 to -348 mV at pH 8.5. A plot of Em2 versus the pH for this redox couple was linear and revealed a change of -53 mV/pH unit, indicating a single protonation event associated with reduction. From this plot, it was concluded that p is <6.0 and p is >8.5 in a proton-modified Nernst equation. In contrast, the midpoint potential for the P1+/N couple (Em1) was found to be -290 mV and was invariant over the pH range 6.0-8.5. These results indicate that the protonated species does not influence either the P1+ or the PN oxidation states. In addition, at physiological pH values, electron transfer is coupled to proton transfer for the P2+/1+ couple. The P-clusters are unique among [Fe-S] clusters in that they appear to be ligated to the protein through a serinate-gammaO ligand (betaSer188) and a peptide bond amide-N ligand (alphaCys88), in addition to cysteinate-S ligands. Elimination of the serinate ligand by replacement with a glycine was found to shift the Em values for both P-cluster couples by greater than +60 mV, however the pH dependence of Em2 was unchanged. These results rule out Ser188 as the protonated ligand responsible for the pH dependence of Em2. The implications of these results in understanding the nitrogenase electron-transfer mechanism are discussed.     

Direct voltammetric observation of redox driven changes in axial coordination and intramolecular rearrangement of the phenylalanine-82-histidine variant of yeast iso-1-cytochrome c

Direct square-wave and cyclic voltammetric electrochemical examination of the yeast iso-1-cytochrome c Phe82His/Cys102Ser variant revealed the intricacies of redox driven changes in axial coordination, concomitant with intramolecular rearrangement. Electrochemical methods are ideally suited for such a redox study, since they provide a direct and quantitative visualization of specific dynamic events. For the iso-1-cytochrome c Phe82His/Cys102Ser variant, square-wave voltammetry showed that the primary species in the reduced state is the Met80-Fe2+-His18 coordination form, while in the oxidized state the His82-Fe3+-His18 form predominates. The addition or removal of an electron to the appropriate form of this variant serves as a switch to a new molecular form of the cytochrome. Using the 2 x 2 electrochemical mechanism, simulations were done for the cyclic voltammetry experiments at different scan rates. These, in turn, provided relative rate constants for the intramolecular rearrangement/ligand exchange and the equilibrium redox potentials of the participating coordination forms: kb,AC = 17 s-1 for Met80-Fe3+-His18 --> His82-Fe3+-His18 and kf,BD > 10 s-1 for His82-Fe2+-His18 --> Met80-Fe2+-His18; E0' = 247 mV for Met80-Fe3+/2+-His18 couple, E0' = 47 mV for His82-Fe3+/2+-His18 couple, and E0' = 176 mV for the cross-reaction couple, His82-Fe3+-His18 + e- --> Met80-Fe2+-His18. Thermodynamic parameters, including the entropy of reaction, DeltaS0'Rxn, were determined for the net reduction/rearrangement reaction, His82-Fe3+-His18 + e- --> Met80-Fe2+-His18, and compared to those for wild-type cytochrome, Met80-Fe3+-His18 + e- --> Met80-Fe2+-His18. For the Phe82His variant mixed redox couple, DeltaS0'Rxn = -80 J/mol.K compared to DeltaS0'Rxn = -52 J/mol.K for the wild-type cyt c couple without rearrangement. Comparison of these entropies indicates that the oxidized His82-Fe3+-His18 form is highly disordered. It is proposed that this high level of disorder facilitates rapid rearrangement to Met80-Fe2+-His18 upon reduction.     

Spectroelectrochemical characterization of the metal centers in carbon monoxide dehydrogenase (CODH) and nickel-deficient CODH from Rhodospirillum rubrum

Carbon-monoxide dehydrogenase (CODH) from Rhodospirillum rubrum contains two metal centers: a Ni-X-[Fe4S4]2+/1+ cluster (C-center) that serves as the COoxidation site and a standard [Fe4S4]2+/1+ cluster (B-center) that mediates electron flow from the C-center to external electron acceptors. Four states of the C-center were previously identified in electron paramagnetic resonance (EPR) and M?ssbauer studies. In this report, EPR-redox titrations demonstrate that the fully oxidized, diamagnetic form of the C-center (Cox) undergoes a one-electron reduction to the Cred1 state (gav = 1.87) with a midpoint potential of -110 mV. The reduction of Cox to Cred1 is shown to coincide with the reduction of an [Fe4S4]2+/1+ cluster in redox-titration experiments monitored by UV-visible spectroscopy. Nickel-deficient CODH, which is devoid of nickel yet contains both [Fe4S4]2+/1+ clusters, does not exhibit EPR-active states or reduced Fe4S4 clusters at potentials more positive than -350 mV.     

Molecular dynamics simulation of cytochrome c3: studying the reduction processes using free energy calculations

The tetraheme cytochrome c3 from Desulfovibrio vulgaris Hildenborough is studied using molecular dynamics simulation studies in explicit solvent. The high heme content of the protein, which has its core almost entirely made up of c-type heme, presents specific problems in the simulation. Instability in the structure is observed in long simulations above 1 ns, something that does not occur in a monoheme cytochrome, suggesting problems in heme parametrization. Given these stability problems, a partially restrained model, which avoids destruction of the structure, was created with the objective of performing free energy calculations of heme reduction, studies that require long simulations. With this model, the free energy of reduction of each individual heme was calculated. A correction in the long-range electrostatic interactions of charge groups belonging to the redox centers had to be made in order to make the system physically meaningful. Correlation is obtained between the calculated free energies and the experimental data for three of four hemes. However, the relative scale of the calculated energies is different from the scale of the experimental free energies. Reasons for this are discussed. In addition to the free energy calculations, this model allows the study of conformational changes upon reduction. Even if the precise details of the structural changes that take place in this system upon individual heme reduction are probably out of the reach of this study, it appears that these structural changes are small, similarly to what is observed for other redox proteins. This does not mean that their effect is minor, and one example is the conformational change observed in propionate D from heme I when heme II becomes reduced. A motion of this kind could be the basis of the experimentally observed cooperativity effects between heme reduction, namely positive cooperativity.     

Characterization of the metal centers of the corrinoid/iron-sulfur component of the CO dehydrogenase enzyme complex from Methanosarcina thermophila by EPR spectroscopy and spectroelectrochemistry

The multienzyme carbon monoxide dehydrogenase complex from Methanosarcina thermophila contains at least two protein components: a CO-oxidizing nickel/iron-sulfur (Ni/Fe-S) component and a cobalt-containing corrinoid/iron-sulfur component (Co/Fe-S). The CO dehydrogenase complex has been shown to synthesize acetyl-CoA from CoA, CH3I, and CO as well as to cleave acetyl-CoA into its methyl, carbonyl, and CoA components as the first step in the catabolism of acetyl-CoA to methane and CO2. Presumed to serve as an acceptor of the methyl group of acetyl-CoA en route to methane, the Co/Fe-S component contains iron, acid-labile sulfur, and a corrinoid cofactor (factor III) that is the site of methylation. Using EPR spectroscopy and spectroelectrochemistry, we characterized the cobalt and Fe-S centers of the Co/Fe-S component. The redox and EPR properties of the metal centers in the isolated Co/Fe-S component are similar to those of the Co/Fe-S component in the CO dehydrogenase enzyme complex, a result that indicates that any protein-protein interaction between components in the complex has little influence on the properties of the metal centers. The corrinoid is maintained in the base-off state with a formal equilibrium reduction potential (E'o) at pH 7.8 of -486 mV for the Co2+/1+ couple that facilitates reduction of the Co2+ state by approximately 12 kcal/mol relative to base-on cobamides. The Co/Fe-S component also contains a [4Fe-4S]2+/1+ cluster with an E'o at pH 7.8 of -502 mV, which is nearly isopotential with the Co2+/1+ couple of the cobamide.     

Multiheme cytochromes from the sulfur-reducing bacterium Desulfuromonas acetoxidans

Two new multiheme cytochromes were isolated from the anaerobic sulfur reducing bacterium Desulfuromonas acetoxidans. They have monomeric molecular masses of 50 and 65 kDa and contain six and eight hemes, respectively. Visible and EPR spectroscopies, in the as-isolated (oxidised) cytochromes, show the presence of only low-spin hemes in the 50-kDa cytochrome, and of high-spin and low-spin hemes in the 65-kDa cytochrome. The EPR spectra of the native 65-kDa cytochrome indicate multiple heme-heme interactions, including integer-spin systems as judged by parallel-mode EPR. The 50-kDa cytochrome has a complex redox pattern, as shown by EPR redox titrations, and contains one heme with unusual characteristics. Both cytochromes cover an extremely wide range of reduction potentials, which go from +100 mV to -375 mV for the 50-kDa cytochrome, and +185 mV to -235 mV for the 65-kDa cytochrome. The two cytochromes were tested for hydroxylamine oxidoreductase activity and polysulfide reductase activity, but neither displayed any activity. In contrast, it was found for the first time that the previously characterised cytochrome c551.5, from the same bacterium is very active in the reduction of polysulfide, which suggests that it acts as a terminal reductase in D. acetoxidans.     

Effect of four helix bundle topology on heme binding and redox properties

We have designed two alternative four helix bundle protein scaffold topologies for maquette construction to examine the effect of helix orientation on the heme binding and redox properties of our prototype heme protein maquette, (alpha-SS-alpha)2, previously described as H10H24 [Robertson, D. E., Farid, R. S., Moser, C. C., Mulholland, S. E., Pidikiti, R., Lear, J. D., Wand, A. J., DeGrado, W. F., and Dutton, P. L. (1994) Nature 368, 425]. Conversion of the disulfide-bridged di-alpha-helical monomer of (alpha-SS-alpha)2 into a single polypeptide chain results in topological reorientation of the helix dipoles and side chains within a 62 amino acid helix-loop-helix monomer, (alpha-l-alpha), which self-associates to form (alpha-l-alpha)2. Addition of an N-terminal cysteine residue to (alpha-l-alpha) with subsequent oxidation yields a 126 amino acid single molecule four helix bundle, (alpha-l-alpha-SS-alpha-l-alpha). Gel permeation chromatography demonstrated that (alpha-SS-alpha)2 and (alpha'-SS-alpha')2, a uniquely structured variant of the prototype, as well as (alpha-l-alpha)2 and (alpha'-l-alpha')2 assemble into distinct four helix bundles as designed, whereas (alpha-l-alpha-SS-alpha-l-alpha) elutes as a monomeric four alpha-helix bundle. Circular dichroism (CD) spectroscopy proves that these peptides are highly alpha-helical, and incorporation of four hemes has little effect on the helical content of the secondary structure. Four heme dissociation constants were evaluated by UV-visible spectroscopy and ranged from the 15 nM to 25 microM range for each of the peptides. The presence of Cotton effects in the visible CD illustrated that the hemes reside within the protein architecture. The equilibrium redox midpoint potentials (Em8) of the four bound hemes in each peptide are between -100 and -280 mV, as determined by redox potentiometry. The heme affinity and spectroelectrochemical properties of the hemes bound to (alpha-l-alpha)2 and (alpha-l-alpha-SS-alpha-l-alpha) are similar to those of the prototype, (alpha-SS-alpha)2, and to bis-histidine ligated b-type cytochromes, regardless of the global architectural changes imposed by these topological rearrangements. The hydrophobic cores of these peptides support local electrostatic fields which result in nativelike heme chromophore properties (spectroscopy, elevated reduction potentials, heme-heme charge interaction, and reactivity with exogenous diatomics) illustrating the utility of these non-native peptides in the study of metalloproteins.     

The redox properties of cytochromes b imposed by the membrane electrostatic environment

The effect of the dipole potential field of extended membrane spanning alpha-helices on the redox potentials of b cytochromes in energy transducing membranes has been calculated in the context of a three phase model for the membrane. In this model, the membrane contains three dielectric layers; (i) a 40-A hydrophobic membrane bilayer, with dielectric constant em = 3-4, (ii) 10-20-A interfacial layers of intermediate polarity, ein = 12-20, that consist of lipid polar head groups and peripheral protein segments, and (iii) an external infinite water medium, ew = 80. The unusually positive midpoint potential, Em = +0.4 V, of the "high potential" cytochrome b-559 of oxygenic photosynthetic membranes, a previously enigmatic property of this cytochrome, can be explained by (i) the position of the heme in the positive dipole potential region near the NH2 termini of the two parallel helices that provide its histidine ligands, and (ii) the loss of solvation energy of the heme ion due to the low dielectric constant of its surroundings, leading to an estimate of +0.31 to +0.37 V for the cytochrome Em. The known tendency of this cytochrome to undergo a large -delta Em shift upon exposure of thylakoid membranes to proteases or damaging treatments is explained by disruption of the intermediate polarity (ein) surface dielectric layer and the resulting contact of the heme with the external water medium. Application of this model to the two hemes (bn and bp) of cytochrome b of the cytochrome bc1 complex, with the two hemes placed symmetrically in the low dielectric (em) membrane bilayer, results in Em values of hemes bn and bp that are, respectively, somewhat too negative (approximately -0.1 V), and much too positive (approximately +0.3 V), leading to a potential difference, Em(bp) - Em(bn), with the wrong sign and magnitude, +0.25 V instead of -0.10 to -0.15 V. The heme potentials can only be approximately reconciled with experiment, if it is assumed that the two hemes are in different dielectric environments, with that of heme bp being more polar.     

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.     

Substrate and cofactor reactivity of a carbon monoxide dehydrogenase-corrinoid enzyme complex: stepwise reduction of iron-sulfur and corrinoid centers, the corrinoid Co2+/1+ redox midpoint potential, and overall synthesis of acetyl-CoA

Cleavage of the acetyl carbon-carbon bond of acetyl-CoA in Methanosarcina barkeri is catalyzed by a high molecular mass multienzyme complex. The complex contains a corrinoid protein and carbon monoxide dehydrogenase and requires tetrahydrosarcinapterin (H4SPt) as methyl group acceptor. Reactions of the enzyme complex with carbon monoxide and with the methyl group donor N5-methyltetrahydrosarcinapterin (CH3-H4SPt) have been analyzed by UV-visible spectroscopy. Reduction of the enzyme complex by CO occurred in two steps. In the first step, difference spectra exhibited peaks of maximal absorbance decrease at 426 nm (major) and 324 nm (minor), characteristic of Fe-S cluster reduction. In the second step, corrinoid reduction to the Co1+ level was indicated by a prominent peak of increased absorbance at 394 nm. Spectrophotometric analyses of the corrinoid redox state were performed on the intact complex at potentials poised by equilibration with gas mixtures containing different [CO2]/[CO] ratios or by variation of the [H+]/[H2] ratio. The corrinoid Co2+/1+ midpoint potential was -426 mV (+/- 4 mV, n = 1.16 electrons, 24 degrees C), independent of pH (pH 6.4-8.0). The results indicated a significant fraction of Co1+ corrinoid at potentials existing in vivo. The reduced corrinoid reacted very rapidly with CH3-H4SPt. Reaction with methyl iodide was slow, and methylation by S-adenosylmethionine was not observed. Tne rate of methyl group transfer from CH3-H4SPt greatly exceeded the rate of CO reduction of enzyme centers. The enzyme complex catalyzed efficient synthesis of acetyl-CoA from coenzyme A, CO, and CH3-H4SPt. During acetyl-CoA synthesis, demethylation of CH3-H4SPt was monitored by the absorbance increase at 312 nm.(ABSTRACT TRUNCATED AT 250 WORDS)     

The possible function of stone ramparts at the nest entrance of the blackstart

The origin of Ibetanull, the Ca2+ current of myotubes from mice lacking the skeletal dihydropyridine receptor (DHPR) beta1a subunit, was investigated. The density of Ibetanull was similar to that of Idys, the Ca2+ current of myotubes from dysgenic mice lacking the skeletal DHPR alpha1S subunit (-0.6 +/- 0.1 and -0.7 +/- 0.1 pA/pF, respectively). However, Ibetanull activated at significantly more positive potentials. The midpoints of the GCa-V curves were 16.3 +/- 1.1 mV and 11.7 +/- 1.0 mV for Ibetanull and Idys, respectively. Ibetanull activated significantly more slowly than Idys. At +30 mV, the activation time constant for Ibetanull was 26 +/- 3 ms, and that for Idys was 7 +/- 1 ms. The unitary current of normal L-type and beta1-null Ca2+ channels estimated from the mean variance relationship at +20 mV in 10 mM external Ca2+ was 22 +/- 4 fA and 43 +/- 7 fA, respectively. Both values were significantly smaller than the single-channel current estimated for dysgenic Ca2+ channels, which was 84 +/- 9 fA under the same conditions. Ibetanull and Idys have different gating and permeation characteristics, suggesting that the bulk of the DHPR alpha1 subunits underlying these currents are different. Ibetanull is suggested to originate primarily from Ca2+ channels with a DHPR alpha1S subunit. Dysgenic Ca2+ channels may be a minor component of this current. The expression of DHPR alpha1S in beta1-null myotubes and its absence in dysgenic myotubes was confirmed by immunofluorescence labeling of cells.     

Midpoint potentials of the mitochondrial cytochromes of Crithidia fasciculata

The midpoint potentials of the mitochondrial respiratory chain cytochromes of the protozoan Crithidia fasciculata at pH 7.2, Em7.2, show great similarity to those measured in higher organisms. Values of Em7.2 for cytochromes a and a3 are +165 and +340 mV. Both c cytochromes have Em7.2 = +230 mV. There are two b cytochromes with the same spectral characteristics with Em7.2 = -20 and -135 mV. These values are compatible with two sites of energy conservation for oxidative phosphorylation in these mitochondria. All cytochrome components show potentiometric titrations with n = 1. There is a fluorescent flavoprotein in these mitochondria with Em7.2 = -40 mV and n =2, whose function is not known.