EPR studies on a Hipip type iron-sulfur center in the succinate dehydrogenase segment of the respiratory chain

In addition to the two species of ferredoxin-type iron-sulfur centers (Centers S-1 and S-2), a Hipip-type iron-sulfur center (Center S-3) has been detected in the reconstitutively active soluble succinate dehydrogenases. E_m7,4 determined in a particulate, antimycin A sensitive succinate-cytochrome $\text{c}$ reductase is +60 ± 15 mV. This center is extremely labile towards oxygen in a manner similar to the reconstitutive activity of the dehydrogenase. Even freshly prepared reconstitutively active enzyme shows a considerably diminished content of Center S-3 relative to flavin and displays a partly modified spectra. All reconstitutively inactive dehydrogenases give rise to a highly modified or no Center S-3 spectra at all. These observations indicate that Center S-3 is a constituent of succinate dehydrogenase and plays a role in the physiological function of the enzyme, $\text{i.e.}$ transferring electrons most probably to ubiquinone.     

EPR studies on two ferredoxin-type iron-sulfur centers in reconstitutively active, inactive, and reactivated soluble succinate dehydrogenases

Two distinct iron-sulfur centers, S-1 and S-2 are present in both reconstitutively active and inactive soluble succinate dehydrogenase preparations in approximately equivalent concentrations to that of bound flavin. The midpoint potentials at pH 7.4 of these centers are ?5 ± 15 mV and ?400 ± 15 mV, respectively. EPR characteristics of Center S-2, observed above 6° K, are not significantly different in the active and inactive dehydrogenases. At lower temperatures, however, major line shape modifications of Center S-2 spectra are observed in the reconstitutively inactive dehydrogenases, but neither in the active dehydrogenase nor in the particulate preparations. This phenomenon may reflect spin-spin interaction between Centers S-1 and S-2. Chemical reactivation of the reconstitutively inactive preparations abolishes this resonance modification and restores the normal line shape. This is a demonstration of another close correlation between a physical property and reconstitutive activity of succinate dehydrogenase.     

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.     

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.     

Characterization of ubisemiquinone radical in the cytochrome b-c1 segment of the mitochondrial respiratory chain

The ubiquinone protein, QP-C, in reduced ubiquinone-cytochrome c reductase (the b?c₁-III complex) shows a stable ubisemiquinone radical when the enzyme is reduced by succinate in the presence of catalytic amounts of succinate dehydrogenase and QP-S. At room temperature using EPR technique the redox titration of the b?c₁-III complex in the presence of redox dyes or succinate/fumarate couple reveals that the ubisemiquinone radical has a midpoint potential of approximately +67 mV at pH 8.0. Further analysis yields E₁ of +83 mV and E₂ of +51 mV corresponding to ($\text{QH}{}_2\text{QH·}$) and ($\text{QH·}\text{Q}$) or other electronated forms, respectively. The equilibrium radical concentration has been found to be affected both by pH and succinate/fumarate couple. At pH 9.0 the radical shows the maximal amplitude and stability. Below pH 7.0, little radical was detected. The electron spin relaxation behavior of ubisemiquinone radical, as examined by microwave power saturation, indicates that the ubisemiquinone radical of QP-C is somewhat isolated from other paramagnetic centers. The effects of phospholipids, QP-S, and other agents on ubisemiquinone radical formation as well as the enzymatic activity of QP-C have been studied in detail.     

Ubisemiquinone radicals from the cytochrome b-c1 complex of the mitochondrial electron transport chain--demonstration of QP-S radical formation

Stable ubisemiquinone radical(s) in the cytochrome $\text{b}\text{?}\text{c}{}_1$-II complex of bovine heart was observed following reduction by succinate in the presence of catalytic amounts of succinate dehydrogenase. The radical was abolished by addition of antimycin A, but a residual radical remained in the presence of excess exogenous Q₂. The radical showed an EPR signal of g = 2.0046 ± .003 at X band (～9.4 GHz) with no resolved hyperfine structure and had a line width of 8.1 ± .5 Gauss at 23°C. The Q band (35 GHz) spectra showed wellresolved $\text{g}$-anisotropy and had a field separation between derivative extrema of 26 ± 1 Gauss. This radical is evidently from QP-C. These observations substantiate that the radical is immobilized and bound to a protein. The QP-S radical was demonstrated in the cytochrome $\text{b}\text{-}\text{c}{}_1$-II complex only in the presence of more than a catalytic amount of succinate dehydrogenase and cytochrome $\text{b}\text{-}\text{c}{}_1$. This signal was not antimycin a inhibitory. The signal amplitude paralleled the reconstitutive enzymic activity of succinate-cytochrome $\text{c}$ reductase from succinate dehydrogenase and the cytochrome $\text{b}\text{-}\text{c}{}_1$-II complex.     

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).     

Low temperature electron paramagnetic resonance studies on iron-sulfur centers in cardiac NADH dehydrogenase

EPR signals arising from at least seven iron-sulfur centers were resolved in both reconstitutively active and inactive NADH dehydrogenases, as well as in particulate NADH-UQ reductase (Complex I). EPR lineshapes of individual iron-sulfur centers in the active dehydrogenase are almost unchanged from that in Complex I. Iron-sulfur centers in the inactive dehydrogenase give broadened EPR spectra, suggesting that modification of iron-sulfur active centers is associated with loss of the reconstitutive activity of the dehydrogenase. With the reconstitutively active dehydrogenase, the E_m8.0 value of Center N-2 (iron-sulfur centers associated with NADH dehydrogenase are designated with prefix N) was shifted to a more negative value than in Complex I and restored to the original value on reconstitution of the enzyme with purified phospholipids.     

Thermodynamic and EPR characterization of mitochondrial succinate-cytochrome c reductase-phospholipid complexes

Succinate-cytochrome c reductase can be easily solubilized in a phospholipid mixture (1:1, lysolecithin:lecithin) in the absence of detergents. The resulting solution contains two b cytochromes with half-reduction potentials of 95 ± 10 mV (b₅₆₁), and 0 ± 10 mV (b₅₆₆) and cytochrome c₁ (E_{m 7.2} = +280±5 mV). The oxidation-reduction midpoint potentials obtained by optical potentiometric titrations are identical to those determined by the EPR titrations and are 40–60 mV higher than the corresponding midpoint potentials of these cytochromes in intact mitochondria. In contrast to detergent-suspended preparations, no CO-sensitive cytochrome b can be detected in the phospholipid-solubilized preparation or intact mitochondria. The half-reduction potential of cytochrome b₅₆₆ is pH-dependent above pH 7.0 (?60 mV/pH unit) while that of b₅₆₁ is essentially pH-independent from pH 6.7–8.5, in contrast to its pH dependence in intact mitochondria. EPR characterizations show the presence of three oxidized low-spin heme-iron signals with g values of 3.78, 3.41 and 3.37. The identification of these signals with cytochromes b₅₆₆ (b_T), b₅₆₁ (b_K) and c₁ respectively is made on the basis of redox midpoint potentials. No significant amounts of oxidized high-spin heme-iron are detectable. In addition, the preparation contains four distinct types of iron-sulfur centers: S₁ and S₂ (E_{m 7.4} = ?260 mV and 0 mV), and two iron-sulfur proteins which are associated with the cytochrome b-c₁ complex: Rieske's iron-sulfur protein (E_{m 7.4} = +280 mV) and Ohnishi's Center 5 (E_{m 7.4} = +35 mV).     

Cobalt cytochrome c: enzymic assays.

An improved synthesis for cobalt-cytochrome $\text{c}$ has been developed; its half reduction potential is ?140 ± 20mV. Reduced ^Cocyt-$\text{c}$³ is oxidized by bovine heart cytochrome $\text{c}$ oxidase at a rate ～45% that of the native cytochrome $\text{c}$. It is not reduced by mitochondrial NADH or succinate cytochrome $\text{c}$ reductase nor by microsomal NADH or NADPH cytochrome $\text{c}$ reductase.     

Reconstitution of succinate-Q reductase.

Reconstitution of succinate-Q reductase is achieved by admixing soluble succinate dehydrogenase (SDH) and ubiquinone-protein-S (QP-S), a new protein isolated from the soluble cytochrome $\text{b-c}{}_1$ complex. The reconstituted reductase catalyzes reduction of Q by succinate. The reaction is fully sensitive to thenoyltrifluoroacetone. The reconstituted reductase (same as succinate-cytochrome $\text{c}$ reductase or submitochondrial particles) does not show “low concentration ferricyanide reductase activity” as soluble dehydrogenase does. In other words, this enzymic site on SDH is occupied by QP-S. When an artificial dye, such as phenazine methosulfate or Wurster's Blue, is used as electron acceptor the rate of oxidation of succinate by SDH is not significantly changed regardless of whether the dehydrogenase is in the free or in the reconstituted succinate-Q reductase forms.     

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.     

Oxidation-reduction properties of the electron acceptors of Photosystem II. II. Redox titration at various pH values of the flash-induced formation of C550 in Chlamydomonas Photosystem II particles lacking the secondary quinone electron acceptor

Redox titrations of the flash-induced formation of C550 (a linear indicator of Q^?) were performed between pH 5.9 and 8.3 in Chlamydomonas Photosystem II particles lacking the secondary electron acceptor, B. One-third of the reaction centers show a pH-dependent midpoint potential (E_m,7.5) = ? 30 mV) for redox couple $\text{Q}\text{Q}{}^{\mathrm{?}}$, which varies by ?60 mV/pH unit. Two-thirds of the centers show a pH-independent midpoint potential (E_mm = + 10 mV) for this couple. The elevated pH-independent E_m suggests that in the latter centers the environment of Q has been modified such as to stabilize the semiquinone anion, Q^?. The midpoint potentials of the centers having a pH-dependent E_m are within 20 mV of those observed in chloroplasts having a secondary electron acceptor. It appears therefore that the secondary electron acceptor exerts little influence on the E_m of $\text{Q}\text{Q}{}^{\mathrm{?}}$. An EPR signal at g 1.82 has recently been attributed to a semiquinone-iron complex which comprises Q^?. The similar redox behavior reported here for C550 and reported by others (Evans, M.C.W., Nugent, J.H.A., Tilling, L.A. and Atkinson, Y.E. (1982) FEBS Lett. 145, 176–178) for the g 1.82 signal in similar Photosystem II particles confirm the assignment of this EPR signal to Q^?. At below ?200 mV, illumination of the Photosystem II particles produces an accumulation of reduced pheophytin (Ph^?). At ?420 mV Ph^? appears with a quantum yield of 0.006–0.01 which in this material implies a lifetime of 30–100 ns for the radical pair P-680⁺Ph^?.     

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.     

Calorimetric measurement of stepwise enthalpy changes for the binding of four oxygens to adult human hemoglobin

The successive enthalpy changes for the four steps of oxygen binding by diphosphoglycerate-free adult human hemoglobin have been measured by direct calorimetry at pH 7.4 and 6°. Average results in kcal/(mole O₂) are: ΔH₁ = ?25.1 ± 2.8; ΔH₂ = ?12.6 ± 3.0, ΔH₃ = ?12.5 ± 3.0, and ΔH₄ = ?10.1 ± 1.4. These results imply a substantial temperature dependence for the cooperativity of O₂ binding by the protein and generally resemble the van't Hoff results by Roughton $\text{et al}$. [Roy. Soc. of London Proc., $\text{B 144}$, 29 (1955)] for sheep hemoglobin at pH 9.1 and a temperature range of 2° to 19°.     

The role of cytochrome b-566 in the electron-transfer chain of Rhodopseudomonas sphaeroides

Spectrophotometric, kinetic, thermodynamic and stoichiometric properties of the low-potential b-type cytochrome of chromatophores from Rhodopseudomonas sphaeroides are reported. Cytochrome b-566 has a double α-band with maxima at 559 and 566 nm. Resolution of the spectrum by full-spectral redox potentiometry showed no indication that the two peaks represent more than one component. The component titrated with E_m,7 ≈ ?80 ± 10 mV. By appropriate choice of wavelength pairs and by subtraction of the contribution due to other components, the kinetics of cytochrome b-566 absorbance changes following flash excitation have been resolved from those of other components. Time-resolved flash spectra corrected for the contributions of other components are consistent with the behavior of both peaks of the α-band as a single kinetic species. The kinetics of cytochrome b-566 in the presence of antimycin show that the reduction of this cytochrome occurred only if cytochrome b-561 was reduced before the flash, either chemically, by poising the ambient redox potential (E_h) below the E_m of cytochrome b-561 (E_m,7 ≈ 50 mV), or photochemically at higher redox potentials by a previous flash. The rate of reduction of cytochrome b-566 varied with E_h. At low E_h (approx. 0 mV) reduction on the first flash showed $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈ 1.25}\text{ms}$; at high E_h (approx. 180 mV) reduction on the second flash showed $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈ 10}\text{ms}$. In the absence of antimycin at E_h ≈ 0 mV, cytochrome b-566 was observed to become rapidly reduced ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈ 500 μ}\text{s}$) and then reoxidized ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈ 2}\text{ms}$) after a single flash. At higher redox potentials (E_h > 80 mV) no kinetic changes which could be unambiguously attributed to cytochrome b-566 were observed following a single flash. The results are interpreted in terms of a Q-cycle mechanism in which the reductant for cytochrome b-566 is the semiquinone formed on oxidation of ubiquinol from the quinone pool. The oxidation of the ubiquinol occurs by a concerted reaction in which one electron is accepted by the Rieske-type FeS center and the other by cytochrome b-566. We suggest that the kinetic characteristics may indicate a pathway for reduction of the b-type cytochromes in which cytochrome b-566 is the immediate electron acceptor and donates to cytochrome b-561 in a serial pathway. The experimental results in the presence of antimycin are compared with data from a computer simulation of the thermodynamic behavior of the chain, and the computer model is shown to provide an excellent fit.     

Magnetic circular dichroism studies of succinate dehydrogenase. Evidence for [2Fe-2S], [3Fe-xS], and [4Fe-4S] centers in reconstitutively active enzyme

Reconstitutively active and inactive succinate dehydrogenase have been investigated by low temperature magnetic circular dichroism (MCD) and EPR spectroscopy and room temperature CD and absorption spectroscopy. Reconstitutively active succinate dehydrogenase is found to contain three spectroscopically distinct Fe-S clusters: S1, S2, and S3. In agreement with previous studies, MCD and CD spectroscopy confirm that center S1 is a succinate-reducible [2Fe-2S]2+,1+ center. The MCD characteristics of center S2 identify it as a dithionite-reducible [4Fe-4S]2+,1+ similar to those in bacterial ferredoxins. EPR power saturation studies and the weakness of the EPR signal from reduced S2 indicate that there is a weak magnetic interaction between centers S1 and S2 in their paramagnetic, S = 1/2, reduced states. Center S3 is identified both by the form of the MCD spectrum and the characteristic magnetization behavior as a reduced [3Fe-xS] center in both succinate- and dithionite-reduced reconstitutively active succinate dehydrogenase. Arguments are presented in favor of centers S2 and S3 being separate centers rather than interconversion products of the same cluster. Reconstitutively inactive succinate dehydrogenase is found to be deficient in center S3. These results resolve many of the controversies concerning the Fe-S cluster content of succinate dehydrogenase and reconcile published EPR data with analytical and core extrusion studies. Moreover, they indicate that center S3 is a necessary requirement for reconstitutive activity and suggest that it is able to sustain ubiquinone reductase activity as a [3Fe-xS] center.     

The NAD-linked α-glycerophosphate dehydrogenase of trypanosomes

NAD-linked α-glycerophosphate dehydrogenase plays a key role in the α-glycerophosphate cycle of $\text{Trypanosoma brucei}$. The activity in cell lysates was ample for this role. The enzyme was activated by salts (e.g. MgCl₂ or NaCl); it had a broad pH-optimum for the reduction of dihydroxyacetone phosphate centred at pH 7.4, with an apparent K_m of 0.5 mM; and it was weakly bound to particulate components of cell lysates. The enzyme from $\text{T. vivax}$ was similar to that of $\text{T. brucei}$. These trypanosomal enzymes resemble that of the trypanosomatid $\text{Crithidia fasciculata}$, but are rather different from the enzymes of mammals, birds and insects.     

Midpoint potential of signal II (slow) in Tris-washed photosystem-II particles

In Tris-washed Photosystem-II particles we are able to induce an EPR signal in the dark by addition of an iridium salt (K₂IrCl₆). This signal is attributed to signal II_s (slow) (D⁺) and the redox titration gives an E_m value of 760 mV for the couple $\text{D}{}^{\mathrm{+}}\text{D}$. On the basis of our previous studies on the equilibrium between D⁺Z and DZ⁺ (K = 10⁴) (Boussac, A. and Etienne, A.L. (1982) Biochem. Biophys. Res. Commun. 109, 1200–1205), we therefore attribute a value of 1 V for the E_m of the $\text{Z}{}^{\mathrm{+}}\text{Z}$ couple. A second effect of K₂IrCl₆ is to modify the spectral characteristics of signal II. We conclude that K₂IrCl₆ is able to change the environment of the species from which signal II_s and signal II_f originate.     

On the purification of nitrite reductase from Thiobacillus denitrificans and its reaction with nitrite under reducing conditions.

Nitrite reductase (cytochrome $\text{cd}$) from $\text{T. denitrificans}$ has been crystallized in high yield in three simple and rapid steps. The spectral absorption ratio at 408 to 280 nm was 1.52. Light absorption spectra in the oxidized and reduced states were virtually identical to those of nitrite reductase from $\text{P. aeruginosa}$. EPR spectroscopy of nitrite reductase at 12° showed a low-spin ferric heme resonance with g-values at 2.52, 2.45 and 1.73 assigned to the d-heme. Reaction of nitrite reductase with nitrite in the presence of the reducing systems [(ascorbate + PMS) or sulfide] resulted in the formation of nitric oxide (confirmed by gas chromatography) which reacted with both $\text{c}$- and $\text{d}$-hemes of nitrite reductase yielding an EPR-detectable enzyme-NO complex with g-values at 2.07, 2.04 and 1.99 and a ¹⁴N hyperfine splitting constant of 22.5 gauss. The amount of nitric oxide produced enzymatically with sulfide as electron donor was only 5% of that found when ascorbate plus PMS served as reductant.To our knowledge the detection of the unique enzyme-NO complex is the first definitive EPR evidence for the mandatory liganding of nitric oxide with pure nitrite reductase during nitrite reduction.