The electron spin relaxation of the electron acceptors of photosystem I reaction centre studied by microwave power saturation.

Photosystem I particles from spinach were reduced by illumination at 77 K. Under these conditions the one-electrom transfer from P-700 resulted in a reduction of only one acceptor molecule of the reaction centre. The EPR signals at g=2.05, 1.94 and 1.86 were attributed to reduced centre A and the smaller signals at g=2.07, 1.92 and 1.89 to reduced centre B. Reduction of both centres by dithionite in the dark lead to signals at g=2.05, 1.99, 1.96, 1.94, 1.92 and 1.89. Thus, the features at g=2.07 and 1.86 disappeared and new signals at g=1.99 and 1.96 were observed. From the spectral changes it followed that the iron-sulphur centres A and B interact magnetically. Temperature dependent EPR spectra demonstrated a faster electron spin relaxation of centre A than of centre B. These conclusions were corroborated using microwave power saturation of the respective EPR signals. The saturation data of the fully reduced centres A and B could not be fitted using the saturation equation for a one-electron spin system. The magnetic interaction between the (4Fe-4S) CENTRes of the electron acceptors A and B resulted in saturation properties which are simular to those of the 2(4Fe-4S) ferredoxin from Clostridium pasteurianum. For centre X a high proportion of homogeneous broadening of the EPR lines was inferred from the inhomogeneity parameter (b=1.83). It was, therefore, concluded that centre X is most probably an anion radical of chlorophyll. From the low temperature necessary for observing the EPR signal of centre X followed that the drastic relaxation enhancement has to be attributed to a magnetic interaction of the anion radical with iron.     

M?ssbauer spectroscopic studies of the nature of centre X of photosystem I reaction centres from the cyanobacterium Chlorogloea fritschii

Reduced photosystem I samples, which give the electron paramagnetic resonance (EPR) signals associated with A, A and B, and A, B and X centres, have been studied using M?ssbauer spectroscopy. The M?ssbauer spectra obtained from each type of sample is different, which indicates that iron is associated with all three centres. The spectra are similar to those obtained from ferredoxins with 4Fe-4S centres and were fitted with oxidized and reduced components, the relative proportions depending on the degree of reduction of the sample as monitored by EPR. The sample which gave only the A EPR signal showed about 26% of the reduced component, the sample which gave A and B EPR signals showed about 48% of the reduced component, while the sample which gave A, B and X EPR signals showed about 65% of the reduced component. The measurements are consistent with X being a 4Fe-S4 centre.     

The orientation of membrane bound radicals. An EPR investigation of magnetically ordered spinach chloroplasts

The orientation of membrane-bound radicals in spinach chloroplasts is examined by electron paramagnetic resonance (EPR) spectroscopy of chloroplasts oriented by magnetic fields. Several of the membrane-bound radicals which possess g-tensor anisotropy display EPR signals with a marked dependence on the orientation of the membranes relative to the applied EPR field. The fraction of oxidized and reduced plastocyanin, P-700, iron-sulfur proteins A and B, and the X center, an early acceptor of Photosystem I, can be controlled by the light intensity during steady-state illumination and can be trapped by cooling. The X center can be photoreduced and trapped in the absence of strong reductants and high pH, conditions previously found necessary for its detection. These results confirm its role as an early electron acceptor in P-700 photo-oxidation. X is oriented with its smallest principal g-tensor axis (g_x) predominantly parallel to the normal to the thylakoid membrane, the same orientation as was found for an early electron acceptor based on time-resolved electron spin polarization studies. We propose that the X center is the first example of a high potential iron-sulfur protein which functions in electron transfer in its ‘;superreduced’; state. We present evidence which suggests that iron-sulfur proteins A and B are 4Fe-4S clusters in an 8Fe-8S protein. Center B is oriented with g_y predominantly normal to the membrane plane. The spectra of center A and plastocyanin do not show significant changes with sample orientation. In the case of plastocyanin, this may indicate a lack of molecular orientation. The absence of an orientation effect for reduced center A is reconcilable with a 4Fe-4S geometry, provided that the electron obtained upon reduction can be shared between any pair of Fe atoms in the center. Orientation of the ‘;Rieske’; iron-sulfur protein is also observed. It has axial symmetry with g close to the plane of the membrane. A model is proposed for the organization of these proteins in the thylakoid membrane.

A new EPR signal was observed in oriented chloroplasts. This broad unresolved resonance displays a g value of 3.2 when the membrane normal is parallel to the field. It shifts to g = 1.9 when the membrane normal is perpendicular to the field. The signal is sensitive to illumination and to washing of the thylakoid membranes of broken chloroplasts. We suggest that there is a relation between this signal and the water-oxidizing enzyme system.     

The orientation of the magnetic axes of the membrane-bound iron-sulfur clusters of spinach chloroplasts

Spinach chloroplast membranes were oriented onto mylar sheets by partial dehydration, and the orientation of the magnetic axes of membrane-bound paramagnetic clusters determined by electron paramagnetic resonance (EPR) spectroscopy. Our results indicate that the reduced Rieske iron-sulfur cluster signal is of orthorhombic symmetry oriented with th gy = 1.90 axis orthogonal to the membrane plane and with the gz = 2.03 axis in the membrane plane; the gx-axis is undetectable, presumably due to its broadness. If the Rieske center is a two-iron iron-sulfur cluster, we conclude that the iron-iron axis lies in the plane of the membrane. Illumination reduces the two bound chloroplast iron-sulfur proteins known as Clusters A and B. Center A is oriented such that gx = 1.86 and gy = 1.94 lie at an angle of about 40, and gz = 2.05 is at approximately 25, to the membrane plane. There are two possible orientations of Cluster B depending on the set of g-values assigned to this cluster. For one set of g-values, gz = 2.04 and gx = 1.89 are oriented in the plane of the membrane while gy = 1.92 is orthogonal to the plane. Alternatively, gz = 2.07 and gy = 1.94 are oriented approximately 50 and 40 to the membrane plane respectively, and gx = 1.80 is in the plane of the membrane. An additional light-induced signal at g = 2.15 oriented orthogonal to the plane is currently unexplained, as are other membrane perpendicular signals seen at g = 2.3 and g = 1.73 in dark-adapted samples.     

Characterization of iron-sulphur centres of plant mitochondria by microwave power saturation.

The electron spin relaxation of iron-sulphur centres and ubisemiquinones of plant mitochondria was studied by microwave power saturation of the respective EPR signals. In the microwave power saturation technique, the experimental saturation data were fitted by a least-squares procedure to a saturation function which is characterized by the power for half-saturation (P1/2) and the inhomogeneity parameter (b). Since the theoretical saturation curves were based on a one-electron spin system, it became possible to differentiate between EPR signals of iron-sulphur centres which have similar g values but different P1/2 values. If the difference in the P1/2 values of the overlapped components was small, no significant deviation from these theoretical saturation curves was observed, as shown for the overlapped signals of centre S-3 and the Ruzicka centre of mung bean mitochondria. By contrast, the microwave power saturation data for the g = 1.93 signal (17--26 K) of Arum maculatum submitochondrial particles reduced by succinate could not be fitted using one-electron saturation curves. Reduction by NADH resulted in a stronger deviation. Since the iron-sulphur centres of Complex I were present only in an unusually low concentration in A. maculatum mitochondria, it was proposed that an iron-sulphur centre of the external NADH dehydrogenase contributes to the spectrum of centre S-1. For mung bean mitochondria, the g = 1.93 signal below 20 K could be attributed mainly to centre N-2. The microwave power saturation technique was also suitable for detecting magnetic interactions between paramagnetic centres. From the saturation data of the complex spectrum attributable to centre S-3 and an interacting ubisemiquinone pair in mung bean mitochondria (oxidized state) followed that centre S-3 has a faster electron spin relaxation than the ubisemiquinone molecules. It is noteworthy that the differences in the relaxation rates were maintained despite the interaction between centre S-3 and the ubisemiquinones. Furthermore, a relaxation enhancement was observed for centre S-1 of A. maculatum submitochondrial particles upon reduction of centre S-2 by dithionite. This indicated a magnetic interaction between centres S-1 and S-2.     

Assignment of the [4Fe-4S] clusters of Ech hydrogenase from Methanosarcina barkeri to individual subunits via the characterization of site-directed mutants

Ech hydrogenase from Methanosarcina barkeri is a member of a distinct group of membrane-bound [NiFe] hydrogenases with sequence similarity to energy-conserving NADH:quinone oxidoreductase (complex I). The sequence of the enzyme predicts the binding of three [4Fe-4S] clusters, one by subunit EchC and two by subunit EchF. Previous studies had shown that two of these clusters could be fully reduced under 10(5) Pa of H2 at pH 7 giving rise to two distinct S1/2 electron paramagnetic resonance (EPR) signals, designated as the g = 1.89 and the g = 1.92 signal. Redox titrations at different pH values demonstrated that these two clusters had a pH-dependent midpoint potential indicating a function in ion pumping. To assign these signals to the subunits of the enzyme a set of M. barkeri mutants was generated in which seven of eight conserved cysteine residues in EchF were individually replaced by serine. EPR spectra recorded from the isolated mutant enzymes revealed a strong reduction or complete loss of the g = 1.92 signal whereas the g = 1.89 signal was still detectable as the major EPR signal in five mutant enzymes. It is concluded that the cluster giving rise to the g = 1.89 signal is the proximal cluster located in EchC and that the g = 1.92 signal results from one of the clusters of subunit EchF. The pH-dependence of these two [4Fe-4S] clusters suggests that they simultaneously mediate electron and proton transfer and thus could be an essential part of the proton-translocating machinery.     

EPR studies by Fe isotopic substitution on the nature of an unknown electron acceptor in Azotobacter vinelandii phosphorylating particles

1. EPR ⁵⁷Fe isotopic substitution studies provide unequivocal evidence that the g = 2.011 signal found in oxidized Azotobacter vinelandii phosphorylating particles is due to an iron-containing structure. The broadening constant determined as a result of this electron—nuclear hyperfine interaction was 15.7 G.

2. A similar signal found in a number of iron—sulfur containing proteins was found by quantitative EPR estimations to exist in a variable but substantial concentration when compared to the intensity of the reduced g = 1.9 type EPR resonance.

3. Reaction of the phosphorylating particles with excess potassium ferricyanide resulted in an alteration of the initial g = 2.011 iron signal resulting in the detection by microwave power studies of at least two different iron species which exhibited major g-values at 1.992 and 2.027.     

EPR studies at 20° K on the mitochondrial respiratory chain

EPR spectrometry at 20°K of oxidized phosphorylating submitochondrial particles has revealed new paramagnetic species, with lines at g = 2.014 (centre) and 1.990 (trough), respectively. The reduction by NADH of the iron-sulphur centre 2 (N.R. Orme-Johnson, W.H. Orme-Johnson, R.E. Hansen, H. Beinert and Y. Hatefi, Proc. Second International Symp. on Oxidases and Related Oxidation-Reduction Systems, Memphis, Tennessee, 1971, in the press) of NADH dehydrogenase, with lines at g = 2.052 and 1.922, is unaffected by rotenone. Succinate also partially reduces this species in phosphorylating sub-mitochondrial particles. An additional species with lines at g = 2.027 (top) and 1.886 is also seen in reduced particles.     

ESR characteristics of Photosystem I in deuterium oxide: Further evidence that electron acceptor A1 is a quinone

The appearance of ESR signals from Photosystem I (PS I) electron acceptors A₁ and A₀ in water or deuterium oxide suspension was followed using a low-temperature photoaccumulation technique. In deuterated samples the A₁ signal was narrowed by a factor of 0.66 compared with the control. This effect was fully reversible upon resuspension of treated samples in H₂O. The narrow ESR signal from deuterated A₁ had similar power saturation characteristics to the normal signal; however, a signal from a second component resolved by deuteration was saturated at higher microwave powers than the control. The power saturation behaviour of A⁻₁ in un-modified reaction centres indicated that it is an anionic semiquinone in a ‘protic’ environment. Deuteration reversibly modified the relative extents of reduction of iron sulphur electron acceptors A and B such that centre B became the more stable electron acceptor. The g-value and line-width of iron sulphur centre X was not modified by deuteration although it appeared to become more efficiently reduced. These results are discussed in the light of current evidence from optical, electron spin polarisation and extraction experiments that suggest that A₁ is a quinone, probably vitamin K-1.     

Characterization of iron-sulphur centres of plant mitochondria by microwave power saturation

The electron spin relaxation of iron-sulphur centres and ubisemiquinones of plant mitochondria was studied by microwave power saturation of the respective EPR signals. In the microwave power saturation technique, the experimental saturation data were fitted by a least-squares procedure to a saturation function which is characterized by the power for half-saturation ($\text{P}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) and the inhomogeneity parameter (b). Since the theoretical saturation curves were based on a one-electron spin system, it became possible to differentiate between EPR signals of iron-sulphur centres which have similar g values but different $\text{P}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ values. If the difference in the $\text{P}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ values of the overlapped components was small, no significant deviation from these theoretical saturation curves was observed, as shown for the overlapped signals of centre S-3 and the Ruzicka centre of mung bean mitochondria. By contrast, the microwave power saturation data for the g = 1.93 signal (17–26 K) of Arum maculatum submitochondrial particles reduced by succinate could not be fitted using one-electron saturation curves. Reduction by NADH resulted in a stronger deviation. Since the iron-sulphur centres of Complex I were present only in an unusually low concentration in A. maculatum mitochondria, it was proposed that an iron-sulphur centre of the external NADH dehydrogenase contributes to the spectrum of centre S-1. For mung bean mitochondria, the g = 1.93 signal below 20 K could be attributed mainly to centre N-2. The microwave power saturation technique was also suitable for detecting magnetic interactions between paramagnetic centres. From the saturation data of the complex spectrum attributable to centre S-3 and an interacting ubisemiquinone pair in mung bean mitochondria (oxidized state) followed that centre S-3 has a faster electron spin relaxation than the ubisemiquinone molecules. It is noteworthy that the differences in the relaxation rates were maintained despite the interaction between centre S-3 and the ubisemiquinones. Furthermore, a relaxation enhancement was observed for centre S-1 of A. maculatum submitochondrial particles upon reduction of centre S-2 by dithionite. This indicated a magnetic interaction between centres S-1 and S-2.     

Primary events in the photosynthetic reaction centre from Rhodopseudomonas spheroides strain R26: Triplet and oxidized states of bacteriochlorophyll and the identification of the primary electron acceptor

ESR studies at approximately 10 °K on the reaction centre complex of the photosynthetic bacterium Rhodopseudomonas spheroides (strain R26), have revealed bacteriochlorophyll triplet states and a component which has an ESR absorption centred at g = 1.82. The triplet-state bacteriochlorophyll is induced only in the light and is only detectable when the reaction-centre bacteriochlorophyll and its primary electron acceptor are reduced; the ESR triplet state signals are composed of both ESR absorption and ESR emission bands. The oxidation-reduction properties of the g = 1.82 component and its flash-induced kinetic behavior in relation to that of P870 are those expected for the primary electron acceptor in bacterial photosynthesis.     

Biochemical and biophysical studies on cytochrome c oxidase. XIX. An EPR study of the photodissociation of carboxycytochrome c oxidase in the presence of azide

1. The photodissociation reaction of the cytochrome c oxidase-CO compound in the presence of azide was studied by EPR at 15°K. Addition of CO in the dark to cytochrome c oxidase, partially reduced (2 electrons per 4 metal ions) in the presence of azide brings about a decrease in intensity of the azide-induced low-spin heme signal at g = 2.9, 2.2 and 1.67 and an increase in intensity of both the low-spin heme signal at g = 3 and the copper signal at g = 2. Subsequent illumination with white light at room temperature of this sample causes an enhancement of the azide-induced signal at g = 2.9, and a decrease in intensity of both signals at g = 3 and g = 2. It is shown that these changes in the EPR spectrum are reversible.

2. These results demonstrate that upon photodissociation, CO is replaced by azide wheras upon incubation in the dark CO expels azide from its binding site in cytochrome c oxidase.

3. Concomitantly with the binding of CO and dissociation of the azide molecule, and vice versa, electron redistributions occur as inferred from the changes in the intensity of the copper signal at g = 2.

4. The results are explained in a model of cytochrome c oxidase with either a common binding site (cytochrome a₃)^* for CO and azide or in a model with anti-cooperative interaction between two different sites of binding.

5. Similar types of experiments with cyanide instead of azide show that cyanide is more firmly bound to partially reduced cytochrome c oxidase than CO and azide. The affinity of ligands for partially reduced enzyme decreases in the sequence: cyanide, CO (dark), azide and CO (illuminated).     

Comparison of the EPR properties of photosystem I iron-sulphur centres A and B in spinach and barley

The properties of Photosystem I iron-sulphur centres A and B from spinach and barley chloroplasts were investigated by electron paramagnetic resonance spectroscopy (EPR). Barley chloroplasts were shown to photoreduce significant amounts of centre B at cryogenic temperatures unlike those from spinach which only photoreduced centre A. Centre B in barley chloroplasts was also reduced by dithionite before centre A and the EPR spectrum of reduced centre B was obtained. Illumination of barley chloroplasts at 15 K where centre B was chemically reduced resulted in the reduction of centre A and the appearance of spectral features indicating interaction between the two reduced centres. The variation of behaviours of iron-sulphur centres A and B between species favours a scheme of electron flow for Photosystem I where either centre A or centre B act as parallel electron acceptors from the earlier acceptor X.     

Three-iron-sulfur centers of pea mitochondria

EPR signals of three distinct types of three-iron-sulfur center were observed in pea mitochondria: the signal of Center S-3 (low-field peak at g = 2.016), the signal of Center ISP-1 (low-field peak at g = 2.024) and the signal of the axial Center ISP-2 with two maxima, at g = 2.027 and 2.016. Succinate increases the signal amplitude of Center ISP-1 and diminishes that of Center ISP-2; malate has an opposite effect. Membrane damage enhances the effect of malate and decreases that of succinate.     

Characterization of the iron-sulfur cluster N7 (N1c) in the subunit NuoG of the proton-translocating NADH-quinone oxidoreductase from Escherichia coli

The proton-pumping NADH-quinone oxidoreductase from Escherichia coli houses nine iron-sulfur clusters, eight of which are found in its mitochondrial counterpart, complex I. The extra putative iron-sulfur cluster binding site with a CXXCXXXCX(27)C motif in the NuoG subunit has been assigned to ligate a [2Fe-2S] (N1c). However, we have shown previously that the Thermus thermophilus N1c fragment containing this motif ligates a [4Fe-4S] (Nakamaru-Ogiso, E., Yano, T., Ohnishi, T., and Yagi, T. (2002) J. Biol. Chem. 277, 1680-1688). In the current study, we individually inactivated four sets of the iron-sulfur binding motifs in the E. coli NuoG subunit by replacing all four ligands with Ala. Each mutant subunit, designated Delta N1b, Delta N1c, Delta N4, and Delta N5, was expressed as maltose-binding protein fusion proteins. After in vitro reconstitution, all mutant subunits were characterized by EPR. Although EPR signals from cluster N1b were not detected in any preparations, we detected two [4Fe-4S] EPR signals with g values of g(x,y,z) = 1.89, 1.94, and 2.06, and g(x,y,z) = 1.91, 1.94, and 2.05 at 6-20 K in wild type, Delta N1b, and Delta N5. The former signal was assigned to cluster N4, and the latter signal was assigned to cluster N1c because of their disappearance in Delta N4 and Delta N1c. Confirming that a [4Fe-4S] cluster ligates to the N1c motif, we propose to replace its misleading [2Fe-2S] name, N1c, with "cluster N7." In addition, because these mutations differently affected the assembly of peripheral subunits by in trans complementation analysis with the nuoG knock-out strain, the implicated structural importance of the iron-sulfur binding domains is discussed.     

M?ssbauer studies of Escherichia coli sulfite reductase complexes with carbon monoxide and cyanide. Exchange coupling and intrinsic properties of the [4Fe-4S] cluster

M?ssbauer studies of the hemoprotein subunit (SiR) of E. coli sulfite reductase have shown that the siroheme and the [4Fe-4S] cluster are exchange-coupled. Here we report M?ssbauer studies of SiR complexed with either CO or CN- and of SiR in the presence of the chaotropic agent dimethyl sulfoxide (Me2SO). The spectra of one-electron-reduced SiR X CN show that all five iron atoms reside in a diamagnetic environment; the ferroheme X CN complex is low spin and the [4Fe-4S] cluster is in the 2+ oxidation state. Titration with ferricyanide affords a CN- complex of oxidized SiR in which the siroheme iron is low spin ferric, with the cluster remaining in the 2+ state. At low temperatures, paramagnetic hyperfine interactions are observed for the iron sites of the cluster, suggesting that it is exchange-coupled to the heme iron. Reduction of one-electron-reduced SiR X CN and SiR X CO yields complexes with "g = 1.94"-type EPR signals showing that the second electron is accommodated by the iron-sulfur cluster. The fully reduced complexes yield well resolved M?ssbauer spectra which were analyzed in the spin Hamiltonian formalism. The analysis shows that the cluster subsites are equivalent in pairs, one pair having properties reminiscent of ferric sites whereas the other pair has features more typical of ferrous sites. The M?ssbauer spectra of oxidized SiR kept in 60% (v/v) Me2SO are virtually identical with those observed for SiR in standard buffer, implying that the coupling is maintained in the presence of the chaotrope. Fully reduced SiR displays an EPR signal with g values of g = 2.53, 2.29, and 2.07. In 60% Me2SO, this signal vanishes and a g = 1.94 signal develops; this transition is accompanied by a change in the spin state of the heme iron from S = 1 (or 2) to S = O.     

The iron-sulphur centres of soluble hydrogenase from Alcaligenes eutrophus.

The soluble hydrogenase (hydrogen:NAD+ oxidoreductase (EC 1.12.1.2) from Alcaligenes eutrophus has been purified to homogeneity by an improved procedure, which includes preparative electrophoresis as final step. The specific activity of 57 mumol H2 oxidized/min per mg protein was achieved and the yield of pure enzyme from 200 g cells (wet weight) was about 16 mg/purification. After removal of non-functional iron, analysis of iron and acid-labile sulphur yielded average values of 11.5 and 12.9 atoms/molecule of enzyme, respectively. p-Chloromercuribenzoate was a strong inhibitor of hydrogenase and apparently competed with NAD not with H2. Chelating agents, CO and O2 failed to inhibit enzyme activity. The oxidized hydrogenase showed an EPR spectrum with a small signal at g = 2.02. On reduction the appearance of a high temperature (50--77 K) signal at g = 2.04, 1.95 and a more complex low temperature (less than 30 K) spectrum at g = 2.04, 2.0, 1.95, 1.93, 1.86 was observed. The pronounced temperature dependence and characteristic lineshape of the signals obtained with hydrogenase in 80--85% dimethylsulphoxide demonstrated that iron-sulphur centres of both the [2Fe-2S] and [4Fe-4S] types are present in the enzyme. Quantitation of the EPR signals indicated the existence of two identical centres each of the [4Fe-4S] and of the [2Fe-2S] type. The midpoint redox potentials of the [4Fe-4S] and the [2Fe-2S] centres were determined to be -445 mV and -325 mV, respectively. Spin coupling between two centres, indicated by the split feature of the low temperature spectrum of the native hydrogenase around g = 1.95, 1.93, has been established by power saturation studies. On reduction of the [Fe-4S] centres, the electron spin relaxation rate of the [2Fe-2S] centres was considerably increased. Treatment of hydrogenase with CO caused no change in EPR spectra.     

EPR studies on the respiratory chain of wild-type Saccharomyces cerevisiae and mutants with a deficiency in succinate dehydrogenase

1. Three nuclear mutants of Saccharomyces cerevisiae deficient in succinate dehydrogenase have been isolated. Two of these mutants are allelic.

2. The amount of covalently bound flavin of submitochondrial particles of the two allelic mutants is about 14% and that of the third mutant about 50% of the amount in wild-type particles. The turnover number of succinate dehydrogenase of particles is decreased in all mutants. The turnover number of fumarate reductase is increased in the two allelic mutants, but decreased in the third mutant.

3. EPR spectra, measured at 82 °K, show that the amplitude of the g = 1.93 signal in particles of the two allelic mutants is less than 10% of that in wild-type particles. It is concluded that iron-sulphur centres other than those of succinate dehydrogenase make only a negligible contribution to the line at g = 1.93 in wild-type particles.

4. EPR measurements below 20 °K show that the amplitude of the signal at g = 2.01 detected in oxidized particles is decreased in particles of the two allelic mutants.

5. A signal with lines at g = 2.027 and g = 1.933 is detected at low temperatures in all particle preparations, even in those from a cytoplasmic petite mutant. It is suggested that this signal is derived from a contaminant and not from the inner membrane.     

Interconversions between the 3Fe and 4Fe forms of the iron-sulfur clusters in the ferredoxin from Thermodesulfobacterium commune: EPR characterization and potentiometric titration

The amount of 3Fe clusters in Thermodesulfobacterium commune ferredoxin is strongly dependent upon the presence of oxygen during the purification. An average of one 3Fe cluster per monomer can be found when the purification is not strictly anaerobic. These clusters are converted into |4Fe-4S| clusters by adding dithionite at usual pH and without adjunction of Fe²⁺. The EPR potentiometric titration reveals the existence of several types of 3Fe clusters with negative midpoint potentials differing by more than 100 mV. When the |4Fe-4S| clusters are partially reduced the EPR signal is composed of two different rhombic components. The component with g_z = 2.04 could be related to a site implicated in the interconversion processes. In the fully reduced state, the spectrum presents the typical features of two interacting |4Fe-4S| clusters as those observed in two |4Fe-4S| bacterial ferredoxins. From the redox titration curves the midpoint potentials of these clusters are estimated at −395 and −435 mV.     

Novel EPR signals associated with FeMoco centres of MoFe protein in MgADP-inhibited turnover of nitrogenase

Two novel electron paramagnetic resonance (EPR) signals arising from the [1Mo-7Fe-9S-homocitrate] (FeMoco) centres of MoFe protein of Klebsiella pneumoniae nitrogenase (Kp1) were observed following turnover under MgATP-limited conditions. The combination of the nitrogenase Fe protein of Clostridium pasteurianum showed similar signals. The accumulation of MgADP under these conditions causes the normal EPR signal of dithionite-reduced Kp1 (with g=4.3, 3.6, 2.01) to be slowly converted to novel signals with g=4.74, 3.32, 2.00 and g=4.58, 3.50, 1.99. These signals do not form in incubation of protein mixtures containing only MgADP, thus they may be associated with trapped intermediates of the catalytic cycle.