Thermodynamic and EPR characterization of iron-sulfur centers in the NADH-ubiquinone segment of the mitochondrial respiratory chain in pigeon heart

Several iron-sulfur centers in the NADH-ubiquinone segment of the respiratory chain in pigeon heart mitochondria and in submitochondrial particles were analyzed by the combined application of cryogenic EPR (between 30 and 4.2 °K) and potentiometric titration.Center N-1 (iron-sulfur centers associated with NADH dehydrogenase are designated with the prefix “N”) resolves into two single electron titrations with E_{m 7.2} values of ?380±20 mV and ?240±20 mV (Centers N-1a and N-1b, respectively). Center N-1a exhibits an EPR spectrum of nearly axial symmetry with g_// = 2.03, g_⊥ = 1.94, while that of Center N-1b shows more apparent rhombic symmetry with g_z = 2.03, g_y = 1.94 and g_x = 1.91. Center N-2 also reveals EPR signals of axial symmetry at g_// = 2.05 and g_⊥ = 1.93 and its principal signal overlaps with those of Centers N-1a and N-1b. Center N-2 can be easily resolved from N-1a and N-1b because of its high E_{m 7.2} value (?20±20 mV).Resolution of Centers N-3 and N-4 was achieved potentiometrically in submitochondrial particles. The component with E_{m 7.2} = ? 240±20 mV is defined as Center N-3 (g_z = 2.10, (g_y = 1.93?), g_x = 1.87); the ?405±20 mV component as Center N-4 (g_z = 2.11, (g_y = 1.93?), g_x = 1.88). At temperatures close to 4.2 °K, EPR signals at g = 2.11, 2.06, 2.03, 1.93, 1.90 and 1.88 titrate with E_{m 7.2} = ?260±20 mV. The multiplicity of peaks suggests the presence of at least two different ironsulfur centers having similar E_{m 7.2} values (?260±20 mV); hence, tentatively assigned as N-5 and N-6.Consistent with the individual E_{m 7.2} values obtained, addition of succinate results in the partial reduction of Center N-2, but does not reduce any other centers in the NADH-ubiquinone segment of the respiratory chain. Centers N-2, N-1b, N-3, N-5 and N-6 become almost completely reduced in the presence of NADH, while Centers N-1a and N-4 are only slightly reduced in pigeon heart submitochondrial particles. In pigeon heart mitochondria, the E_{m 7.2} of Center N-4 lies much closer to that of Center N-3, so that resolution of the Center N-3 and N-4 spectra is not feasible in mitochondrial preparations. E_{m 7.2} values and EPR lineshapes for the other ironsulfur centers of the NADH-ubiquinone segment in the respiratory chain of intact mitochondria are similar to those obtained in submitochondrial particle preparations. Thus, it can be concluded that, in intact pigeon heart mitochondria, at least five iron-sulfur centers show E_{m 7.2} values around -250 mV; Center N-2 exhibits a high E_{m 7.2} (?20±20 mV), while Center N-1a shows a very low E_{m 7.2} (?380±20 mV).     

EPR signals of NADH: Q oxidoreductase. Shape and intensity.

(1) The EPR spectrum of Center 1 of NADH dehydrogenase in isolated Complex I or submitochondrial particles from beef heart consists of two overlapping nearly axial signals of the same intensity. They are defined as Center 1a (gll = 0.021, gl = 1.938) and Center 1b (gll = 2.021, gl = 1.928). (2) The line shape of the EPR spectrum of the Center 3+4 can be interpreted as an overlap of two rhombic signals of the same intensity. We define Center 3 by the g-values: gz=2.103, gy = 1.93-1.94, gx=1.884, and Center 4 by the values gz=2.04, gy=1.92-1.93, gx=1.863. (3) Direct quantitation of the individuals signals as well as computer stimulation suggests that the amount of the Centers 1a and 1b is only 25% of that of the other individuals centers and FMN. As EPR spectra of beef-heart submitochondrial particles at 10-20 K are nearly identical to those of Complex I, the same relative concentrations of the Fe-S centers are also present in the particles. (4) The signals either observed by us in EPR spectra of Complex I and submitochondrial particles at 4.2 K and high microwave powers can now be explained without assuming more than 5 paramagnetic centers in NADH dehydrogenase.     

Thermodynamic and EPR characteristics of two ferredoxin-type iron-sulfur centers in the succinate-ubiquinone reductase segment of the respiratory chain.

Two distinct ferredosin-type iron-sulfur centers (designated as Centers S-1 and S-2) are present in the soulble succinate dehydrogenase in approximately equivalent concentrations to that of bound flavin. Both Centers S-1 and S-2 exhibit electron paramagnetic resonance absorbance in the reduced state at the same magnetic field (gz = 2.03, gy = 1.93, and gx = 1.91) with similar line shape. Center S-2 is reducible only chemically with dithionite and remains oxidized under physiological conditions. Thus, its functional role is unknown; however, thermodynamic and EPR characterization of this iron-sulfur center has revealed important molecular events related to this dehydrogenase. The midpoint potentials of Centers S-1 and S-2 determined in the soluble succinate dehydrogenase preparations are -5 +/- 15 mV and -400 +/- 15 mV, respectively, while corresponding midpoint potentials determined in particulate preparations, such as succinate-cytochrome c reductase or succinate-ubiquinone reductase, are 0 +/- 15 mV and -260 +/- 15 mV. Reconstitution of soluble succinate dehydrogenase with the cytochrome b-c1 complex is accompanied by a reversion of the Center S-I midpoint from -400 +/- 15 mV to -250 +/- 15 mV with a concomitant restoration of antimycin A-sensitive succinate-cytochrome c reductase activity. There observations indicate that, during the reconstitution process, Center S-I is restored to its original molecular environment. In the reconstitutively active succinate dehydrogenase, the relaxation time of Center S-2 is much shorter than that of S-1, thus Center S-2 spectra are well discernible only below 20 K (at 1 milliwatt of power), while the resonance absorbance of Center S-1 is detectable at higher temperatures and readily saturates below 15 K. Over a wide temperature range the power saturation of Center S-1 resonance absorbance is relieved by Center S-2 in the paramagnetic state, and the Center S-2 central resonance absorbance is broadened by Center S-1 spins, due to a spin-spin interaction between these centers. These observations indicate an adjacent location of these centers in the enzyme molecule. In reconstitutively inactive enzymes, subtle modification of the enzyme structure appears to shift the temperature dependence of Center S-2 relaxation to the higher temperature. Thus the EPR signals of Center S-2 are also detectable at higher temperature. In this system a splitting of the central peak of the Center S-2 spectrum due to spin-spin interaction was observed at extremely low temperatures, while this was not observed in reconstitutively active enzymes or in paritculate preparations. This spin-spin interaction phenomena of inactive enzymes disappeared upon chemical reactivation with concomitant appearance of the reconstitutive activity. These observations provide a close correlation between the molecular integrity of the enzyme and its physiological function.     

The orientation of iron-sulfur clusters and a spin-coupled ubiquinone pair in the mitochondrial membrane.

Oriented multilayers made from beef heart and yeast mitochondria and submitochondrial particles were studied using electron paramagnetic resonance. EPR signals from membrane-bound iron-sulfur clusters and from a spin-coupled ubiquinone pair are highly orientation dependent, implying that these redox centers are fixed in the membrane at definite angles relative to the membrane plane. Typically the iron-iron axis (gz) of the binuclear iron-sulfur clusters is in the membrane plane. This finding is discussed in terms of the protein structure. The tetranuclear iron-sulfur clusters can have their gz axis either perpendicular or parallel to the membrane plane, but intermediate orientation was not observed.     

Iron-sulfur N-1 clusters studied in NADH-ubiquinone oxidoreductase and in soluble NADH dehydrogenase

Two N-1 type iron-sulfur clusters in NADH-ubiquinone oxidoreductase (Complex I, EC 1.6.5.3) were potentiometrically resolved: one was titrated as a component with a midpoint oxidation-reduction potential of -335 mV at pH 8.0, and with an n-value equal to one; the other as an extremely low midpoint potential component (Em 8.0 less than -500 mV). These two clusters are tentatively assigned to N-1b and N-1a, respectively. Cluster N-1b is completely reducible with NADH and has a spin concentration of about 0.8/FMN. Its EPR spectrum can be simulated as a single rhombic component with principal g values of 2.019, 1.937, and 1.922, which correspond to the Center 1 reported earlier by Orme-Johnson, N. R., Hansen, R. E., and Beinert, H. (1974) J. Biol. Chem. 249, 1922-1927. At extremely low oxidation-reduction potentials (less than -450 mV), additional EPR signals emerge with apparent g values of gz = 2.03, gy = 1.95, and gx = 1.91, which we assign to cluster N-1a. It is difficult, however, to simulate the detailed spectral line shape of this component as a single rhombic component, suggesting some degree of protein modification or interaction with a neighboring oxidation-reduction component. EPR spectra of soluble NADH dehydrogenase, containing 5-6 g atoms of non-heme iron and 5-6 mol of acid-labile sulfide/mol of FMN, were examined. Signals from at least two iron-sulfur species could be distinguished in the NADH-reduced form: one of an N-1b type spectrum; the other of a spectrum with g values of 2.045, 1.95, and 1.87 (total of about 0.5 spin equivalents/FMN). This is the first example of an N-1 type signal detected in isolated soluble NADH dehydrogenase.     

Characterization of iron-sulfur clusters in rat liver submitochondrial particles by electron paramagnetic resonance spectroscopy. Alterations produced by chronic ethanol consumption

Iron-sulfur clusters present in rat liver submitochondrial particles were characterized by ESR at temperatures between 30 and 5.5 K combined with potentiometric titrations. The spectral and thermodynamic characteristics of the iron-sulfur clusters were generally similar to those previously reported for pigeon or bovine heart submitochondrial particles. Clusters N-1a, N-1b, N-2, N-3 and N-4 of NADH dehydrogenase had midpoint oxidation-reduction potentials at pH 7.5 of ?425, ?265, ?85, ?240 and ?260 mV, respectively. Clusters S-1 and S-3 of succinate dehydrogenase had midpoint potentials of 0 and +65 mV, respectively. The iron-sulfur cluster of electron-transferring flavoprotein-ubiquinone oxidoreductase exhibited the g_z signal at g = 2.08 and had a midpoint potential of +30 mV. This signal was relatively prominent in rat liver compared to pigeon or bovine heart.Submitochondrial particles from rats chronically treated with ethanol (36% of total calories, 40 days) showed decreases of 20–30% in amplitudes of signals due to clusters N-2, N-3 and N-4 compared to those from pair-fed control rats. Signals from clusters N-1b, S-1, S-3 and electron-transferring flavoprotein-ubiquinone oxidoreductase were unaffected. Microwave power-saturation behavior was similar for both submitochondrial particle preparations, suggesting that the lower signal amplitudes reflected a lower content of these particular clusters. NADH dehydrogenase activity was significantly decreased (46%), whilst succinate dehydrogenase activity was elevated (25%), following chronic ethanol consumption. The results indicate that chronic ethanol treatment leads to an alteration of the structure and function of the NADH dehydrogenase segment of the electron transfer chain. This alteration is one of the factors contributing to the lower respiration rates observed following chronic ethanol administration.     

Effects of ethanol and acetaldehyde on iron-sulfure centers in the mitochondrial respiratory chain.

Incubation of submitochondrial particles with relatively low concentrations of ethanol (20–100 mm) or acetaldehyde (1–10 mm) produces alterations in the electron paramagnetic resonance spectra of the iron-sulfur centers in the NADH dehydrogenase segments of the respiratory chain. The iron-sulfur centers in the NADH dehydrogenase region are most sensitive to both ethanol and acetaldehyde, in comparison to the iron-sulfur centers in succinate dehydrogenase and the cytochrome b-c region. Centers N-3, 4, N-5, 6 and N-1b are affected after relatively short incubation periods (3–30 min) while center N-2 shows considerable sensitivity over somewhat longer incubations (20–90 min). The most ethanol-sensitive center in the succinate dehydrogenase region of the respiratory chain is high potential iron-sulfur protein-type center S-3. Potentiometric analysis shows that these alterations are not due to simple changes in the redox state caused by addition of dissolved oxygen. Changes in the electron paramagnetic resonance spectra can be correlated with decreased rates of oxidation of NADH and, to a lesser extent, succinate in both ethanol- and acetaldehyde-treated submitochondrial particles.     

Thermodynamic and EPR characteristics of a HiPIP-type iron-sulfur center in the succinate dehydrogenase of the respiratory chain.

In addition to the two species of ferredoxin-type iron-sulfur centers (Centers S-1 and S-2), a third iron-sulfur center (Center S-3), which is paramagnetic in the oxidezed state analogous to the bacterial high potential iron-sulfur protein, has bwen detected in the reconstitutively active soluble succinate dehydrogenase preparation. Midpoint potential (at pH 7.4) of Center S-3 determined in a particulate succinate-cytochrome c reductase is +60 +/- 15 mV. In soluble form, Center S-3 becomes extremely labile towards oxygen or ferricyanide plus phenazine methosulfate similar to reconstitutive activity of the dehydrogenase. Thus, even freshly prepared reconstitutively active enzyme preparations show EPR spectra of Center S-3 which correspond approximately to 0.5 eq per flavin; in particulate preparations this component was found in a 1:1 ratio to flavin. All reconstitutively inactive dehydrogenase preparations that Center S-3 is an innate constituent of succinate dehydrogenase and plays an important role in mediating electrons from the flavoprotein subunit to most probably ubiquinone and then to the cytochrome chain.     

Existence of two distinct Hipip-type iron-sulfur centers in mitochondria.

Two distinct Hipip type iron-sulfur centers are present in pigeon heart mitochondria. These two can be distinguished by their EPR spectra which differ in the detailed line shape, field position and temperature dependence. These two seem to correspond to Center S-3, and an iron-sulfur protein purified by Ruzicka and Beinert. They exhibit different thermodynamic behavior and topographical location in the mitochondrial membrane.     

Mitochondrial respiratory chain of Tetrahymena pyriformis: the properties of submitochondrial particles and the soluble b and c type pigments.

Submitochondrial particles isolated from Tetrahymena pyriformis contain essentially the same redox carriers as those present in parental mitochondria: at pH 7.2 and 22 degree C there are two b-type pigments with half-reduction potentials of --0.04 and --0.17 V, a c-type cytochrome with a half reduction potential of 0.215 V, and a two-component cytochrome a2 with Em7.2 of 0.245 and 0.345 V. EPR spectra of the aerobic submitochondrial particles in the absence of substrate show the presence of low spine ferric hemes with g values at 3.4 and 3.0, a high spin ferric heme with g =6, and a g=2.0 signal characteristic of oxidized copper. In the reduced submitochondrial particles signals of various iron-sulfur centers are observed. Cytochrome c553 is lost from mitochondria during preparation of the submitochondrial particles. The partially purified cytochrome c553 is a negatively charged protein at neutral pH with an Em7.2 of 0.25 V which binds to the cytochrome c-depleted Tetrahymena mitochondria in the amount of 0.5 nmol/mg protein with KD of 0.8.10(-6) M. Reduced cytochrome c553 serves as an efficient substrate in the reaction with its own oxidase. The EPR spectrum of the partially purified cytochrome c553 shows the presence of a low spin ferric heme with the dominant resonance signal at g=3.28. A pigment with an alpha absorption maximum at 560 nm can be solubilized from the Tetrahymena cells with butanol. This pigments has a molecular weight of approx. 18 000, and Em7.2 of--0.17 V and exhibits a high spin ferric heme signal at g=6.     

Identification of a stable ubisemiquinone and characterization of the effects of ubiquinone oxidation-reduction status on the Rieske iron-sulfur protein in the three-subunit ubiquinol-cytochrome c oxidoreductase complex of Paracoccus denitrificans

The ubiquinol-cytochrome c oxidoreductase (cytochrome bc1) complex from Paracoccus denitrificans exhibits a thermodynamically stable ubisemiquinone radical detectable by EPR spectroscopy. The radical is centered at g = 2.004, is sensitive to antimycin, and has a midpoint potential at pH 8.5 of +42 mV. These properties are very similar to those of the stable ubisemiquinone (Qi) previously characterized in the cytochrome bc1 complexes of mitochondria. The micro-environment of the Rieske iron-sulfur cluster in the Paracoccus cytochrome bc1 complex changes in parallel with the redox state of the ubiquinone pool. This change is manifested as shifts in the gx, gy, and gz values of the iron-sulfur cluster EPR signal from 1.80, 1.89, and 2.02 to 1.76, 1.90, and 2.03, respectively, as ubiquinone is reduced to ubiquinol. The spectral shift is accompanied by a broadening of the signal and follows a two electron reduction curve, with a midpoint potential at pH 8.5 of +30 mV. A hydroxy analogue of ubiquinone, UHDBT, which inhibits respiration in the cytochrome bc1 complex, shifts the gx, gy, and gz values of the iron-sulfur cluster EPR signal to 1.78, 1.89, and 2.03, respectively, and raises the midpoint potential of the iron-sulfur cluster at pH 7.5 from +265 to +320 mV. These changes in the micro-environment of the Paracoccus Rieske iron-sulfur cluster are like those elicited in mitochondria. These results indicate that the cytochrome bc1 complex of P. denitrificans has a binding site for ubisemiquinone and that this site confers properties on the bound ubisemiquinone similar to those in mitochondria. In addition, the line shape of the Rieske iron-sulfur cluster changes in response to the oxidation-reduction status of ubiquinone, and the midpoint of the iron-sulfur cluster increases in the presence of a hydroxyquinone analogue of ubiquinone. The latter results are also similar to those observed in the mitochondrial cytochrome bc1 complex. However, unlike the mitochondrial complexes, which contain eight to 11 polypeptides and are thought to contain distinct quinone binding proteins, the Paracoccus cytochrome bc1 complex contains only three polypeptide subunits, cytochromes b, c1, and iron-sulfur protein. The ubisemiquinone binding site and the site at which ubiquinone and/or ubiquinol bind to affect the Rieske iron-sulfur cluster in Paracoccus thus exist in the absence of any distinct quinone binding proteins and must be composed of domains contributed by the cytochromes and/or iron-sulfur protein.     

Studies of the function of the membrane-bound iron-sulfur centers of the photosynthetic bacterium Chromatium vinosum

Chromatophores from the photosynthetic bacterium, Chromatium vinosum, have been prepared which photoreduce NAD⁺ with either succinate or reduced dichlorophenolindophenol as electron donors. NAD⁺ reduction is inhibited by uncouplers as well as inhibitors of cyclic photophosphorylation. These chromatophores contain several bound iron-sulfur centers which have been detected by low-temperature EPR spectroscopy. One center, having a g 2.01 EPR signal in the oxidized state, has E_m7.5 = +50 mV and is partially reduced by succinate in the dark. Three iron-sulfur centers having g 1.93 EPR signals have been resolved by redox titration, and the E_m7.5 values of these centers are ?50, ?175 and ?250 mV, respectively. Studies of the involvement of these centers in electron transfer from donors to NAD⁺ have indicated that the center with E_m = ?50 mV is succinate reducible in the dark and appears to be analogous to center S-1 of succinic dehydrogenase in other systems. An additional g 1.93 iron-sulfur center can be photoreduced in the presence of electron donors and this reduction is inhibited by uncouplers. The possible role of the two low-potential iron-sulfur centers in relation to the dehydrogenases functioning in NAD⁺ reduction is considered.     

Iron-sulphur centres in mitochondria from Arum maculatum spadix with very high rates of cyanide-resistant respiration.

X-band electron-paramagnetic-resonance spectroscopy at 4.2--77K combined with measurements of oxidation-reduction potential was used to identify iron--sulphur centres in Arum maculatum (cuckoo-pint) mitochondria. In the oxidized state a signal with a derivative maximum at g = 2.02 was assigned to succinate dehydrogenase centre S-3. Unreduced particles showed additional signals at g = 2.04 and 1.98 (at 9.2 GHz), which may be due to a spin-spin interaction. In the reduced state a prominent signal at g = 1.93 and 2.02 was resolved into at least three components that could be assigned to centres S-1 and S-2 of succinate dehydrogenase (midpoint potentials -7 and -240 mV respectively at pH 7.2) and a small amount of centre N-1b (e'o= -240 mV) of NADH-ubiquinone reductase. In addition, changes in line shape around -10 mV indicated the presence of a fourth component in this signal. The latter was more readily reduced by NADH than by succinate, suggesting that it might be associated with the external NADH dehydrogenase. The iron-sulphur centres of NADH-ubiquinone reductase were present in an unusually low concentration, indicating that the alternative, non-phosphorylating, NADH dehydrogenase containing a low number of iron-sulphur centres may be responsible for most of the high rate of oxidation of NADH.     

Characterization of the iron-sulfur protein of the mitochondrial outer membrane partially purified from beef kidney cortex.

The iron-sulfur protein present in the mitochondrial outer membrane has been partially purified from beef kidney cortex mitochondria by means of selective solubilization followed by DEAE-cellulose chromatography. The EPR spectrum of the iron-sulfur protein with g-values at 2.01, 1.94 and 1.89 was well resolved up to 200 K which is unusual for an iron-sulfur protein. Analyses confirmed a center with two iron and two labile sulfur atoms in the protein. By measuring the effect of oxidation-reduction potential on the EPR signal amplitude, midpoint potentials at pH 7.2 were determined both for the purified iron-sulfur protein, +75 (+/- 5) mV, and in prepared mitochondrial outer membrane, +62 (+/- 6) mV. At pH 8.2 slightly lower values were indicated, +62 and 52 mV, respectively. The oxidation-reduction equilibrium involved a one electron transfer. A functional relationship to the rotenone-insensitive NADH-cytochrome c oxidoreductase in the mitochondrial outer membrane is suggested. Both this activity and the iron-sulfur center were sensitive to acidities slightly below pH 7 in contrast to the iron-sulfur centers of the inner membrane.     

Characterization of the iron-sulfur protein of the mitochondrial outer membrane partially purified from beef kidney cortex

The iron-sulfur protein present in the mitochondrial outer membrane has been partially purified from beef kidney cortex mitochondria be means of selective solubilization followed by DEAE-cellulose chromatography. The EPR spectrum of the iron-sulfur protein with g-values at 2.01, 1.94 and 1.89 was well resolved up to 200 K which is unusual for an iron-sulfur protein. Analyses confirmed a center with two iron and two labile sulfur atoms in the protein. By measuring the effect of oxidation-reduction potential on the EPR signal amplitude, midpoint potentials at pH 7.2 were determined both for the purified ironsulfur protein, +75 (±5) mV, and in prepared mitochondrial outer membrane, +62 (±6) mV. At pH 8.2 slightly lower values were indicated, +62 and 52 mV, respectively. The oxidation-reduction equilibrium involved a one electron transfer. A functional relationship to the rotenone-insensitive NADH-cytochrome c oxidoreductase in the mitochondrial outer membrane is suggested. Both this activity and the iron-sulfur center were sensitive to acidities slightly below pH 7 in contrast to the iron-sulfur centers of the inner membrane.     

The spatial relationships and structure of the binuclear iron-sulfur clusters in succinate dehydrogenase.

Two binuclear iron-sulfur clusters (designated S-1 and S-2) are present in succinate dehydrogenase in approximately equal concentration to that of flavin. The large difference in their midpoint potentials (0 and -400 mV, respectively, in the soluble enzyme) permits the acquisition of individual electron paramagnetic resonance spectra characterized by nearly identical rhombic g tensors (gz = 2.025, gy = 1.93, gx = 1.905). Spin-coupling between the two centers is manifested by broadening and splitting of spectra of reconstitutively active and inactive succinate dehydrogenase, respectively, as the temperature is lowered; relief of power saturation of Center S-1 spectra on reduction of Center S 2; and observation of half-field ("delta ms = 2") signals in the dithionite-reduced enzyme. Saturation behavior of fully reduced dehydrogenase is consistent with the presence of S-1 and S-2 at equivalent concentrations/molecule. Simulation of the spin-coupled spectra, assuming dipolar interaction, provides information on molecular structure. Electron paramagnetic resonance spectra of the enzyme in 80% dimethylsulfoxide are nearly identical to the characteristic binuclear spectra obtained with adrenodoxin. These data provide additional evidence for binuclear structure of both Center S-1 and S-2. The extremely fast relaxation of Center S-2 at low temperatures would imply either an anomalously small value of J or an alternative relaxation mechanism, possibly due to the coupling between S-1 and S-2.     

Intramitochondrial positions of cytochrome haem groups determined by dipolar interactions with paramagnetic cations.

E.p.r.(electron-paramagnetic-resonance) spectra of the ferricytochromes were studied in normal and 'nickel-plated' pigeon heart mitochondria and pigeon heart submitochondrial particles. NiCL2 added to either mitochondria or particles was bound completely to the membranes, but none was transported across the vesicles. Hence, any perturbations of the haem e.p.r. spectra by Ni(II) should occur only for those cytochromes in close proximity to the exterior surface. Whenever Ni(II) can approach to within 1 nm of cytochrome haem. the consequent acceleration of the haem e.p.r. relaxation kinetics should elicit dipolar line broadening. Relaxation acceleration should also increase the incident power level required to saturate the haem e.p.r. signal. In pigeon heart mitochondria, at least three e.p.r. resonances, attributable in part to cytochromes c1, bK and br, are observed at gz=3.3 resonance. In these submitochondrial particles, the peak at gz=3.5 is missing, and the resonance at gz=3.6 resolves into two components, neither of which is sensitive to added Ni(ii). Addition of free haemin (ferric, a paramagnetic anion) to intact mitochondria elicits the same e.p.r. signal changes as does a preparation of submitochondrial particles. Saturation curves for cytochrome oxidase obtained for e.p.r. spectra of the high-spin form (g = 6) and the low-spin form (gz=3.1) also reveal no effect of Ni(II) on the haem e.p.r. relaxation in either mitochondria or inverted submitochondrial particles. Further, Ni(II) fails to alter the spectra or saturation properties of cytochrome c in either mitochondria or submitochondrial particles therefrom. Only with a 50-fold molar excess of Ni(II) can one accelerate the e.p.r. relaxation of cytochrome c in aqueous solution, although other more subtle types of magnetic interactions may occur between the cytochrome and either Ni(II) or ferricyanide. Addition of haemin to mitochondria likewise failed to alter the e.p.r. characteristics of either cytochrome c or cytochrome oxidase. The present observations strongly suggest that cytochromes bK, br and c1 reside on the exterior surface of the inner mitochondrial membrane. On the other hand, we find no positive evidence for the location of cytochrome c or cytochrome oxidase haem groups within 1 nm of either membrane surface. Because of possible shielding effects from the protein moieties, however, we cannot unequivocally assign the location of the haem groups to the membrane interior. The present results are not inconsistent with the observations of other investigators who used different techniques. However, it is clear that any model of energy coupling in mitochondrial oxidative phosphorylation must account for the positioning of all the b-c cytochrome haem groups on the outside.     

Beef-heart submitochondrial particles: a mixture of mitochondrial inner and outer membranes.

1. EPR spectra at 9 GHz and 83 degrees K of NADH-reduced anaerobic beef-heart submitochondrial particles, prepared from mitochondria by sonication and centrifugation, contain a signal (gz equals to 2.01, gy equals to 1.94, gx equals to 1.89) due to an iron-sulphur center of the mitochondrial outer membrane. 2. The ratio of inner and outer membranes in submitochondrial particles is not greatly different from that in beef-heart mitochondria. 3. Beef-heart submitochondrial particles free from outer-membrane contamination have been prepared by free-flow electrophoresis. EPR spectra at 83 degrees K of such particles are presented.     

Coupling site I and the rotenone-sensitive ubisemiquinone in tightly coupled submitochondrial particles

The rotenone-sensitive g = 2.00 low temperature EPR signal attributed to ubisemiquinone is observed in submitochondrial particles during coupled electron transfer from NADH to oxygen and from succinate to NAD+. The signal is seen only in the presence of oligomycin added to induce the respiratory control (7-9 with NADH and 3-4 with succinate) and it disappears in the presence of uncouplers (CCCP or gramicidin D). No reduction of the iron-sulfur center N-2 in the presence of 20 mM succinate and cyanide is observed, thus suggesting that N-2 is not in equilibrium with the ubiquinone pool. A hypothesis is proposed on delta mu H+ generation coupled with electron transfer between iron-sulfur center N-2 and the ubiquinone pool.