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Query: EC:1.3.5.1 (
succinate dehydrogenase
)
8,177
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Extensively or completely activated preparations of beef heart
succinate dehydrogenase
have been investigated by electron paramagnetic resonance (EPR) techniques at 6 to 97 K. Reductive titrations with dithionite and rapid kinetic studies were performed with various types of soluble and membrane-bound preparations of the enzyme. The following components were detected and their behavior analyzed: a free radical, presumably arising from the covalently bound flavin on reduction, two iron-sulfur centers of the
ferredoxin
type, the signals of which appear on reduction, and a highpotential iron-sulfur component, detectable in the oxidized state. The high-potential component was only detected in
complex II
and inner-membrane preparations. This component and one of the
ferredoxin
-type centers were present in amounts close to stoichiometric with the flavin and were reduced by substrate. The other
ferredoxin
-type center was present in amounts between 0.1 and 0.5 times that of the flavin and was reduced only by dithionite. Of the components reduced by succinate, however, only a fraction (up to 50% of the high-potential iron-sulfur center and 40-60% of the
ferredoxin
-type iron-sulfur center) was reduced within the turnover time of the enzymes; In
complex II
not more than about 10% of the flavin appeared in the semiquinone form at any time. Soluble, purified preparations behaved similarly except that the high-potential component was nearly or completely absent and extensive accumulation of the free radical occurred (up to 70 to 80% of the flavin) in titration and kinetic experiments. No significant difference was observed between the rates of semiquinone formation and the reduction of the
ferredoxin
-type or high-potential centers by the substrate. Also no qualitative differences in the properties studied in this work became apparent between prepatations containing 4 or 8 iron atoms, respectively.
...
PMID:Iron-sulfur components of succinate dehydrogenase: stoichiometry and kinetic behavior in activated preparations. 16 76
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.
...
PMID:Thermodynamic and EPR characteristics of a HiPIP-type iron-sulfur center in the succinate dehydrogenase of the respiratory chain. 17 56
E.p.r. (electron-paramagnetic-resonance) spectra of ubisemiquinone (QH) organic radicals and all of the known iron-sulphur centres were studied in normal and 'nickle-plated' pigeon heart mitochondria, submitochondrial particles and submitochondrial particles from which
succinate dehydrogenase
had been removed. Incubation of pigeon heart mitochondria, submitochondrial particles or
succinate dehydrogenase
-depleted submitochondrial particles with substrate in the presence of pure O2 results in the accumulation of Q-H. In mitochondria, the e.p.r. spectrum of Q-H is characterized by in-homogeneous line broadening. A heterogeneous population of semiquinones appears to be partly responsible for these effects in mitochondria. Additon of Ni(II) to mitochondria renders saturation of the Q-H resonance more difficult. On the other hand, the resonance in either submitochondrial particles or
succinate dehydrogenase
-depleted particles is narrower than the same spectrum in mitochondria, and saturates like a homogeneous line. The presence of Ni(II) in either of these preparations, further, has no effect on either the A-H spectrum or the saturation curve. Therefore QH appears to be situated on the exterior surface of the mitochondrion. Likewise, the e.p.r. spectra and saturation curves of iron-sulphur centre N-2 exhibit characteristics of inhomogeneous line broadening, not only in intact mitochondria but also in both submitochondrial particles and
succinate dehydrogenase
-depleted particles. Because of the small pool size of centre N-2, this effect is likely to arise from a spin interaction with some other component in the membrane. Ni(II) has no effect on the saturation in centre N-2 in mitochondria or submitochondrial particles, and only a marginal effect in the
succinate dehydrogenase
-depleted preparation. These results are indeterminate with respect to the position of centre N-2 in the membrane; but suggest that its distance from the
succinate dehydrogenase
binding site is on the order of 1 nm. All of the other
ferredoxin
-type iron-sulphur centres in both preparations were not affected by paramagnetic ions. Homogeneous e.p.r. spectra and saturation curves are observed for both of the HiPIP-type (high-potential iron-sulphur protein-type) iron-sulphur centres in mitochondrial centres S-3 and bc-3. Addition of No(II) to intact mitochondria results in a dipolar interaction with centre bc-3. No effect was observed on centre S-3 in either preparation. A comprehensive model is presented for the structure of the respiratory electron-transport system in mitochondria, based on e.p.r. relaxation studies in the present and the preceding paper. There is no direct evidence for transmembrane electron flow through any of the known energy-coupling sites in mitochondria, so that direct hydrogen atom transfer across the membrane (as a combination of H+ translocation coupled to electron flow) does not occur...
...
PMID:Intramitochondrial positions of ubiquinone and iron-sulphur centres determined by dipolar interactions with paramagnetic ions. 18 59
The coupling constants J between the iron atoms in
ferredoxin
type iron-sulfur proteins containing binuclear clusters were evaluated by two parallel methods. The temperature dependence of the EPR linewidths and integrated abosrption intensities are both related to the energy of the first excited state. The values of J obtained were: center S-1 in
succinate dehydrogenase
, 90 cm-1; Rieske's iron-sulfur center, 65 cm-1;
adrenodoxin
, 270 cm-1. The behavior of iron-sulfur center N-1a in NADH:UQ reductase was also examined; its similarity to that of center S-1 indicates that center N-1a is also a binuclear iron-sulfur center, with J = 90 cm-1. Greater rhombic distortion present in the EPR spectrum of a binuclear cluster was associated with smaller values of J.
...
PMID:Determination of the exchange integral in binuclear iron-sulfur clusters in proteins of varying complexity. 19 6
An analysis of the paramagnetic components present in mitochondria isolated from the poky mutant of Neurospora crassa is described. The study was undertaken with a view to shedding light on the nature of the cyanide- and antimycin A-resistant alternative terminal oxidase which is present in these preparations. Of the
ferredoxin
-type iron-sulfure centers, only Centers S-1 and S-2 of
succinate dehydrogenase
could be detected in significant quantities. Paramagnetic centers attributable to Site I were virtually absent. In the oxidized state, at least two 'high potential iron sulfur' centers could be distinguished and these were attributed to Center S-3 of
succinate dehydrogenase
and a second component analogous to that found in mammalian systems. Much of the Center S-3 signal was in a highly distorted state which was apparently dependent upon the presence of an accompanying free radical species. At lower field positions, a succinate-reducible signal peaking around g = 3.15 was found. This signal is caused by a low spin heme species, presumably the cytochrome c which is the only major cytochrome in these mitochondria. At even lower field positions, signals attributable to iron in a field of low symmetry at g = 4.3 and multiple high spin heme species around g = 6, could be distinguished. The effects of salicylhydroxamic acid, an inhibitor of the alternative oxidase, were tested on these components. Effects could be seen on at least one high spin heme component and also partially upon the distorted Center S-3 signal converting part of it to a signal indistinguishable from center S-3. Some increase in the g = 4.3 iron signal was also noted. No effects of the inhibitor on the
ferredoxin
-type centers were detected.
...
PMID:An EPR analysis of cyanide-resistant mitochondria isolated from the mutant poky strain of Neurospora crassa. 21 9
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.
...
PMID:The spatial relationships and structure of the binuclear iron-sulfur clusters in succinate dehydrogenase. 22 Feb 62
Two techniques have been applied to the determination of the number and type (2-Fe, 4-Fe) of iron-sulfur centers in the iron-sulfur flavoprotein
succinate dehydrogenase
[succinate:(acceptor) oxidoreductase, EC 1.3.99.1]. One procedure uses p-CF3C6H4SH as an extrusion reagent and Fourier transform 19F nuclear magentic resonance as the method of detection and quantitation of extruded cores of these centers in the form of [Fe2S2(SRF)4]2- and [Fe4S4(SRF)4]2- (RF = p-C6H4CF3). The second procedure, interprotein core transfer, involves thiol displacement of iron-sulfur cores followed by specific core transfer to the apoproteins of Bacillus polymyxa
ferredoxin
and
adrenodoxin
. Detection and quantitation are accomplished by electron paramagnetic resonance of reduced proteins at low temperatures. Both procedures clearly show that
succinate dehydrogenase
contains two dimeric (Fe2S2) and one tetrameric (Fe4S4) centers per mole of histidyl flavin, accounting for all eight nonheme iron and eight labile sulfur atoms found by chemical analysis. These results remove uncertainties created by the less than stoichiometric amounts of binuclear centers detected by electron paramagnetic resonance after dithionite reduction and provide secure characterization of the iron-sulfur centers in this enzyme.
...
PMID:Characterization of the iron-sulfur centers in succinate dehydrogenase. 22 82
In the present work the effects of corticosterone restitution were examined in female rats with chronic streptozotocin (SZ)-induced diabetes upon intact liver mitochondrial function and the activities of 3-hydroxybutyrate dehydrogenase (HBD),
succinate dehydrogenase
(SD) and cytochrome c oxidase (Cox) of the ruptured organelle. The liver mitochondrial function was analyzed by the respiration and the osmotic oscillatory behaviour. Respiration was measured by polarographic method and both the state 3 of active respiration (S3) and the respiratory control (RC) were determined using the following substrates: 3-hydroxybutyrate, succinate and malate-glutamate. The oscillatory behaviour was measured using as parameters the damping factors (DF) which are the ratios of amplitudes of two consecutive peaks or troughs of the spectrophotometrical tracings of this phenomenon. A group of control normal rats (N) and the following three groups of diabetic rats were studied: controls (D), adrenalectomized (D +
ADX
) and adrenalectomized with corticosterone restitution (D +
ADX
+ C). The results of mitochondrial respiration showed that the mean values of S3 and RC decreased with the three substrates in the group D +
ADX
+ C compared with D +
ADX
group (p < 0.001). This group demonstrated a significant increase of S3 and RC values of the respiration compared with the D group. The oscillatory behaviour of liver mitochondria of D +
ADX
+ C group demonstrated a significant increase in the DF of peaks and troughs compared with D +
ADX
group. The values of DF of the latter group were not significantly different from the N group. The behaviour of the enzymes activities of ruptured liver mitochondria were different for each enzyme in the different groups of treated rats. Thus, in the D +
ADX
+ C group the mean value of the activity of HBD significantly decreased, that of the Cox increased (p < 0.02) and that of SD did not show any variation compared with the corresponding values of the D +
ADX
group. Likewise, the mean value of HBD activity in this latter group was similar to that of the N group and that of Cox activity was lesser (p < 0.01) than that of the D group. The conclusion is drawn that corticosterone has significant additional diabetogenic effects upon biochemical functions of liver mitochondria in the SZ-induced diabetic state which could occur through the hormone cellular receptors.
...
PMID:Effects of withdrawal of glucocorticoids on improving the function and enzymatic activities of liver mitochondria in female diabetic rats. 166 73
Succinate dehydrogenase is a conserved membrane-bound enzyme consisting of two nonidentical subunits: a flavo iron-sulfur protein (Fp) subunit, containing a covalently bound flavin, and an iron-sulfur protein (Ip) subunit. Bacillus subtilis
succinate dehydrogenase
in wild type bacteria and 12 well characterized
succinate dehydrogenase
-defective mutants were examined by low temperature EPR spectroscopy to characterize the enzyme and study subunit location and biosynthesis of its iron-sulfur clusters. The wild type B. subtilis enzyme contains iron-sulfur clusters which are analogous to clusters S-1 and S-3 of bovine heart
succinate dehydrogenase
but with slightly different EPR characteristics. Spins from cluster S-2 were not detectable as in the case of the intact form of bovine heart
succinate dehydrogenase
. However, dithionite reduction of the B. subtilis enzyme greatly enhanced spin relaxation of the
ferredoxin
-type cluster S-1, indicating the presence of the cluster S-2. Iron-sulfur cluster S-1 was found to be assembled in soluble
succinate dehydrogenase
subunits in the cytoplasm, but only if full-length Fp polypeptides and relatively large fragments of Ip polypeptides were present. Cluster S-1 was not detected in mutants with soluble mutated Fp polypeptides or in a mutant totally lacking Ip subunit polypeptide. Iron-sulfur clusters S-1, S-2, and S-3 were assembled also when the covalently bound flavin in the Fp subunit was absent. Clusters S-1 and S-3 in the membrane-bound flavin-deficient
succinate dehydrogenase
were not reduced by succinate but could be reduced by electron transfer from NADH dehydrogenase via the menaquinone pool.
...
PMID:Characterization by electron paramagnetic resonance and studies on subunit location and assembly of the iron-sulfur clusters of Bacillus subtilis succinate dehydrogenase. 298 99
A simple procedure for preparation of highly purified soluble succinate-ubiquinone reductase from bovine heart mitochondrial particles is described. The enzyme exhibits four major bands on sodium dodecyl sulfate gel electrophoresis and contains (nmol per mg protein): covalently bound flavin, 6; non-heme iron, 53; acid-labile sulfur, 50; cytochrome b-560 heme, 1.2. The enzyme catalyzes thenoyltrifluoroacetone, or carboxin-sensitive (pure non-competitive with Q2) reduction of Q2 by succinate with a turnover number close to that in parent submitochondrial particles. The succinate reduced enzyme exhibits
ferredoxin
-type iron-sulfur center EPR-signal (g = 1.94 species) and a semiquinone signal (g = 2.00). An oxidized preparation shows a symmetric signal centered around g = 2.01. An unusual dissociation of the enzyme in the absence of a detergent is described. When added to the assay mixture from a concentrated protein-detergent solution, the enzyme does not reduce Q2 being highly reactive towards ferricyanide ('low Km ferricyanide reactive site'; Vinogradov, A.D., Gavrikova, E.V. and Goloveshkina, V.G. (1975) Biochem. Biophys. Res. Commun. 65, 1264-1269). The ubiquinone reductase, not the ferricyanide reductase was observed when the enzyme was added to the assay mixture from the diluted protein-detergent solutions. Thus the dissociation of
succinate dehydrogenase
from the complex occurs in the absence of a detergent dependent on the concentration of the protein-detergent complex in the stock preparation where the samples for the assay are taken from. An active antimycin-sensitive succinate-cytochrome c reductase was reconstituted by admixing of the soluble succinate-ubiquinone reductase and the cytochrome b-c1 complex, i.e., from the complexes which both contain the ubiquinone reactivity conferring protein (QPs). Cytochrome c reductase was also reconstituted from the succinate-ubiquinone reductase and succinate-cytochrome c reductase containing inactivated
succinate dehydrogenase
. The reconstitution experiments suggest that there exists a specific protein-protein (or lipid) interaction between QPs and a certain component(s) of the b-c1 complex.
...
PMID:Studies on the succinate dehydrogenating system. Isolation and properties of the mitochondrial succinate-ubiquinone reductase. 299 19
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