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.     

Adenine nucleotides regulate the functional transition in mitochondrial H+-ATPase and the kinetic behaviour of its ATP-synthetase form

The kinetics of the SMP-catalyzed Pi-ATP exchange and oxidative phosphorylation was studied at variable [MgATP] + + [MgADP] and [MgATP]/[MgADP]. The existence on F1 of a center with a low affinity was demonstrated (KM = 0.4-2.7 mM). Saturation of this center with the Mg2+-complex of one of the nucleotides is obligatory for H+-ATPase to exhibit its ATP synthetase activity. It was found that with a decrease of [MgATP]/[MgADP] the lag periods, tau, of the reactions and KM(Pi) also show a decrease. Besides, in the Pi-ATP exchange reactions delta microH+ (steady-state) diminishes and SMP coupling is enhanced (the Vhydr/Vsynth ratio is decreased). Preincubation of SMP with MgADP eliminates the lags but does not affect the course of the steady-state reaction. It is concluded that F1 when bound to MgATP or MgADP changes to a "more" or "less coupled" conformational state, thus determining the rate of conversion to the ATP-synthetase functional state (ko = tau-1), the threshold potential of this conversion and the kinetic behaviour of ATP-synthetase (KM for Pi).     

Intracellular free iron in liver tissue and liver homogenate: studies with electron paramagnetic resonance on the formation of paramagnetic complexes with desferal and nitric oxide.

Treatment of intact liver and liver homogenate with sodium nitrite, or desferal, brings about the appearance of g = 2.03 and g = 4.3 electron paramagnetic resonance spectroscopy (EPR) signals, respectively. The g = 2.03 signal is conditioned by the formation of dinitrosyl complexes of Fe(II); the g = 4.3 signal is related to the appearance of paramagnetic desferal-Fe(III) complexes. Desferal and sodium nitrite were administered successively into liver homogenate, resulting in only a g = 4.3 EPR signal. And, vice versa, if desferal was administered after sodium nitrite, there appeared only the signal with g = 2.03. These data testify to the fact that one and the same endogenous free iron is included in both paramagnetic centers. The concentration of iron ions was measured in intact tissue according to the formation of dinitrosyl-iron complexes and desferal-iron complexes. It was 33.2 +/- 4.6 and 20.3 +/- 4.0 nmol/g of tissue weight, respectively. The data obtained testify to the fact that free endogenous iron is present in intact tissue. Possibilities of the EPR method for estimation of the content of intracellular free iron are discussed.     

EPR signals from cytochrome c oxidase.

1. The major EPR signals from native and cytochrome c-reduced beef heart cytochrome c oxidase (EC 1.9.3.1) are characterized with respect to resonance parameters, number of components and total integrated intensity. A mistake in all earlier integrations and simulations of very anisotropic EPR signals is pointed out. 2. The so-called Cu2+ signal is found to contain at least three components, one "inactive" form and two nearly similar active forms. One of the latter forms, corresponding to about 20% of the total EPR detectable Cu, has not been observed earlier and can only be resolved in 35 GHz spectra. It is not reduced by cytochrome c and is thought to reflect some kind of inhomogeneity in the enzyme preparation. The 35 GHz spectrum of the cytochrome c reducible component shows a rhombic splitting and can be well simulated with g-values 2.18, 2.03 and 1.99. The origin of such a unique type of Cu2+ spectrum is discussed. 3. The low-spin heme signal in the oxidized enzyme (g = 3.03, 2.21, 1.45) is found to correspond closely to one heme and shows no signs of interaction with other paramagnetic centres. 4. The high-spin heme signals appearing in partly reduced oxidase are found to consist of at least three species, one axial and two rhombic types. An integration procedure is described that allows the determination of the total integral intensity of high-spin heme EPR signals only by considering the g = 6 part of the signals. In a titration with ascorbate and cytochrome c the maximum intensity of the g = 6 species corresponds to 23% of the enzyme concentration.     

Identification of electron spin resonance signals of ribonucleotide reductase in animal tissues with high proliferative activity

A new ESR signal (doublet with hyperfine splitting of 20 gauss and g = 2.005) was found for animal tissues having high level of proliferative activity. This signal is shown to be due to radical enzyme ribonucleotide reductase. The results reported for spleen development suggest that there is a correlation between changes in the enzyme activity during the first week of neonatal development and intensity of ESR doublet signal.     

Characterization of the respiratory nitrate reductase of Klebsiella aerogenes as a molybdenum-containing iron-sulfur enzyme.

1. In respiratory nitrate reductase I of Klebsiella aerogenes, 0.24 atom of molybdenum, eight iron-sulfur groups and four tightly bound, non-heme iron atoms per molecule of enzyme (Mr 260 000) are found. 2. EPR spectra at 83 degrees K of oxidized and reduced nitrate reductase I show complex lines at g = 2.02 and g = 1.98, which are more intense in the reduced than in the oxidized enzyme. The resonances, the shape and intensity of which are rather temperature insensitive, are attributed to two species of paramagnetic molybdenum. In dithionite-reduced enzyme all these lines are saturated at the same microwave power of 15 mW. This is not the case in oxidized enzyme, where the resonance at g = 2.02 is hard to saturate. Addition of nitrate to dithionite-reduced reductase I decreases the intensity of the EPR lines to about that of oxidized enzyme. The participation of molybdenum in the electron transfer process has been discussed. 3. At 18 degrees K the oxidized enzyme exhibits an axial-symmetrical signal with g parallel = 2.10 and g = 2.03, and a signal with unknown symmetry at g = 2.015. Upon reduction by dithionite, a ferredoxin type of signal is observed with g values at 2.05, 1.95 and 1.88, while the g = 2.015 signal disappears. Reoxidation by nitrate causes a concomitant disappearance of the ferredoxin type of signal and reappearance of the g = 2.015 signal; hence iron-sulfur centres participate in the transfer of electrons to nitrate. 4. Nitrate reductase II, containing only two (Mr 117 000 and 57 000) of the three subunits found in nitrate reductase I and lacking the tightly bound iron, does not exhibit the axial-symmetrical signal (g = 2.10 and 2.03). Thus, it suggested that this signal in nitrate reductase I stems from an iron centre in the low-molecular weight subunit (Mr 52 000). 5. Inhibition studies confirm the participation of metals in the transfer of electrons from reduced benzylviologen to nitrate and show that the binding sites for these substrates are different.     

Computer simulation of ESR signals of liver paramagnetic centers

Changes of paramagnetic centres concentration characterized by g-factors values of 1.94, 2.2, and 2.03 in the rat liver were studied by ESR method under acute intoxication by diethylnitrosamine (DENA) and at preliminary threefold treatment of animals with butylhydroxytoluene (BHT). A protective effect of BHT can be explained by its stabilizing action of the membrane structures. A comparison has been carried out with a similar study of paramagnetic centres in the experiment of chronic intoxication by DENA. A simulation was performed of the liver tissue ESR spectra by means of special computer program. The parameters of simulated ESR spectra of the liver tissue with due regard for ESR signal g 2.03 corresponded to the parameters of the experimental spectra. Confirmations were obtained for the nature and number of paramagnetic centres in the liver tissue.     

Multiple sites of inhibition of mitochondrial electron transport by chloramphenicol in Neurospora crassa

Abstract The effects in vitro of chloramphenicol on the mitochondrial electron transport of Neurospora crassa were investigated under phosphorylating, non-phosphorylating and uncoupled conditions. The antibiotic acted at more than one site of the respiratory chain: exogenous NADH dehydrogenase, Complex I, the rotenone-resistant by-pass and the alternative oxidase, although an unspecific effect could not be totally excluded.     

Relationships of respiratory chain and ATP-synthetase in energized mitochondria

The present study reveals that the previously described effect of ATP-synthetase inhibition concomitant with inhibition of respiratory chain functioning may be observed at different absolute values of delta psi on the mitochondrial membrane. This fact points out that the membrane potential is not a unique regulator in coupling of ATP-synthetase and respiratory chain activities. We found, using the double-inhibitor titration technique, that ATP-synthetase inhibition induces proportional inhibition of respiratory chain enzymes and vice versa respiratory chain inhibition induces proportional inhibition of ATP-synthetase. This effect is shown to exist only when osmolarity is close to 150-300 (mosM) (in the physiological range). The coupling effectivity (ADP/O) of mitochondria under these conditions is maximal. Under conditions of high osmolarity (400-600 mosM) the respiratory chain and ATP-synthetase behave as if they were coupled by bulk phase delta -mu H+, from the kinetic point of view.     

Differential regulation by trophic conditions of phosphorylating and non-phosphorylating NADP(+)-dependent glyceraldehyde-3-phosphate dehydrogenases in Chlorella fusca.

The two NADP(+)-dependent glyceraldehyde-3-phosphate dehydrogenases present in the green alga Chlorella fusca, namely, the phosphorylating (chloroplastic) enzyme and the non-phosphorylating (cytosolic) enzyme, are differently affected by the trophic conditions prevailing in the cell cultures. The addition of metabolizable sugars to cell cultures growing in the light promotes a marked decrease of the phosphorylating enzyme activity down to a barely detectable cellular level. In contrast, the cellular level of the non-phosphorylating enzyme is even enhanced in the presence of such sugars. These effects are not observed, however, with a number of non-assimilable sugar analogs. After sugar removal, a recovery of the phosphorylating activity--in a process which is inhibited by cycloheximide but not by lincomycin--is observed in illuminated cells but not in darkness, thus indicating a light-dependent nuclear synthesis of the chloroplastic enzyme. It seems therefore that the two dehydrogenases are adaptative enzymes subject to differential regulation by nutritional conditions.     

Study of the respiratory chain in Micrococcus luteus (lysodeikticus) by electron-spin-resonance spectroscopy

Low-temperature electron spin resonance spectroscopy was used to investigate the redox centres of Micrococcus luteus membranes. Three different types of iron-sulphur centres were distinguished. Two of these, a [4Fe-4S]3+-type cluster giving rise to a signal at g = 2.01 in the oxidized state and a [2Fe-2S] cluster with a spectrum at g = 2.03 and 1.93 in the reduced state, were attributable to succinate dehydrogenase. Another, generating signals in the reduced state at g = 2.027, 1.90 and 1.78 was identified as a 'Rieske' iron-sulphur centre. This latter cluster had a mid-point potential (pH 7.0) of +130 mV. In addition, signals characteristic of high-spin ferric haem (g = 6.20), low-spin ferric haem (g = 3.67, 3.36 and 3.01) and Cu2+ (g = 2.18 and 2.02) were also detected. The ferric-haem features, together with the Cu2+ and 'Rieske' centres, were enriched in membrane residues insoluble in Triton X-100, which are known from difference spectroscopy to contain cytochromes b-560, c-550 and a-601 (aa3 oxidase). The signals demonstrated by electron spin resonance for M. luteus membranes showed marked similarities to those documented for the complexes II, III, and IV of mitochondria. However, signals analogous to complex I (NADH-ubiquinone reductase) could not be demonstrated for M. luteus membranes.     

Proton translocation in membranes of submitochondrial particles]

Effect of an electrophilous inhibitor, chlorophenacyl, on energy-dependent functions of submitochondrial particles is studied. Chlorophenacyl at concentrations up to 1 mM is found practically not to affect the generation of membrane potential under NADH and succinate oxidation and ATP hydrolysis and to be a strong inhibitor of oxidative phosphorylation and reverse electron transport. The mechanism of the inhibition of energy-dependent functions of submitochondrial particles with chlorophenacyl is different from that of electron transport inhibitor, energy transport inhibitors and classical uncoupling agents--protonophors. The data obtained are suggested to be due to the existence of two ways of proton translocation in submitochondrial particle membrane, phosphorylating and non-phosphorylating, the effect of chlorophenacyl being directed on phosphorylating way only.     

Effect of hyperbaric oxygenation on paramagnetic centers in the rabbit myocardium during experimental myocardial infarction

Changes in paramagnetic centres (PC) concentration in rabbit's myocardial muscle were studied under experimental myocardial infarction during 168 hours by means of ESR-spectroscopy. PC characterized by ESR signal with g = 3.0 was found. It was shown that hyperbaric oxygenation did not affect PC content in the infarction zone, and resulted in an increase of PC concentration with g = 1.94 and g = 2.0 in the intact myocardial zone.     

Engineering a central metabolic pathway: glycolysis with no net phosphorylation in an Escherichia coli gap mutant complemented with a plant GapN gene.

A cDNA fragment containing the Pisum sativum GapN gene, which encodes the non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase, was cloned in a prokaryote expression vector. This construct enabled Escherichia coli strain W3CG, a mutant which lacks the glycolytic phosphorylating G3P dehydrogenase, to grow aerobically on sugars. The functionally complemented mutant exhibited high levels of the catalytically active plant enzyme, which renders 3-phosphoglycerate and NADPH, thus bypassing the first substrate level phosphorylation step of the glycolysis. As expected if such a glycolytic bypass would be operative in vivo, this clone failed to grow anaerobically on sugars in contrast to W3CG clones complemented with phosphorylating glyceraldehyde-3-phosphate dehydrogenases. According to the irreversible catabolic character of the non-phosphorylating reaction, the GapN-complemented clone was unable to grow on gluconeogenic substrates. This metabolic engineering approach demonstrates that a pure catabolic Embden-Meyerhof pathway with no net energy yield is feasible.     

Evidence for chemiosmotic coupling of electron transport to ATP synthesis in spinach chloroplasts

In spinach chloroplasts it has been shown that (1) the size of the proton gradient under phosphorylating conditions is smaller than under non-phosphorylating conditions; (2) ADP, ATP or Dio-9, added under non-phosphorylating conditions, decrease the rate of electron transport but increase the size of the proton gradient; (3) ADP, ATP or Dio-9 inhibit not only electron transport but also the rate of decay of the proton gradient; (4) the H⁺/e⁻ ratio under non-phosphorylating conditions is 1.0. It is not affected by ADP, ATP or Dio-9.

These results show that protons pass out of the thylakoids at the site of ATP synthesis and that this leakage is inhibited by ADP, ATP or Dio-9, compounds that interact with the site of ATP synthesis. As these compounds do not alter the H⁺/e⁻ ratio the formation of the proton gradient must be an intermediate between electron transport and ATP synthesis. These data are in support of the chemiosmotic theory of coupling of electron transport to ATP synthesis.     

Stimulations of oxygen uptake by electron transfer inhibitors

The stimulation of oxygen uptake induced in avocado tissue slices by amytal, azide and cyanide has been studied. The effects of these inhibitors on O₂ uptake and on phosphorylation suggest the coexistence of phosphorylating and non-phosphorylating electron transfer systems in the fruit. The reason for the stimulations of O₂ uptake is believed to be the result of an increased supply of a limiting cofactor to the phosphorylating sites. The increased availability of cofactor per site is due to the inhibition of part of the cytochrome chain and the consequent reduction in the number of active phosphorylating sites.     

EPR and low temperature spectrophotometric study of the phototransformation products of bacteriorhodopsin]

It is shown that BR and intermediate products of its phototransformation P600, P550 and P415 (the maximum at -196 degrees C at 419 nm) are not paramagnetic. Illumination of samples containing P415 (P419) at -- 196 degrees C with light in the region of 360-480 nm results in the formation of paramagnetic centres with a sunglet spectrum deltaH=18 Oe and g=2.002 (R1). In parallel formation of a new photoproduct P421 in the absorption spectrum is observed. During subsequent heating at -140 degrees C formation of an asymmetric signal with deltaH=45 Oe and g=2.006 and g=2.03 was observed. In the absorption spectra a dark transition. P421-P565 was observed under the same conditions. P565 differs from initial BR P570 as to its photochemical properties. R1 is identified as retinal radical, R2 as a peroxide radical of the BR-complex lipids. Paramagnetic, spectral, and photochemical properties of some products of BR transformation are compared. A scheme of oxidative-phosphorylation processes with participation of Mn ions in BR phototransformation.     

Proton efflux through the chloroplast ATP synthase (CF0 . CF1) in the presence of sulfhydryl-modifying agents

The rate of photosynthetic electron transport measured in the absence of ADP and Pi is stimulated by low levels of Hg2+ or Ag+ (50% stimulation approximately or equal to 3 Hg2+ or 6 Ag+/100 chlorophyll) to a plateau equal to the transport rate under normal phosphorylating conditions (i.e. +ADP, +Pi). Chloroplasts pretreated in the light under energizing conditions with N-ethylmaleimide show a similar stimulation of non-phosphorylating electron transport. The stimulations of non-phosphorylating electron transport by Hg2+, Ag+ and N-ethylmaleimide are reversed by the CF1 inhibitor phlorizin, the CF0 inhibitor triphenyltin chloride, and can be further stimulated by uncouplers such as methylamine. The Hg2+ and N-ethylmalemide stimulations, but not the Ag+ stimulation, are completely reversed by low levels of ADP (2 microM), ATP (2 microM), AND Pi (400 microM). Ag+, which is a potent inhibitor of ATP synthesis, has little or no effect upon phosphorylating electron transport (+ADP, +Pi). Concomitant with the stimulations of non-phosphorylating electron transport by Hg2+, Ag+ and ADP + Pi, there is a decrease in the level of membrane energization (as measured by atebrin fluorescence quenching) which is reversed when the CF0 channel is blocked by triphenyltin. These results suggest that modification of critical CF1 sulfhydryl residues by Hg2+, Ag+ or N-ethylmalemide leads to the loss of intra-enzyme coupling between the transmembrane proton-transferring and the ATP synthesis activities of the CF0-CF1 ATP synthase complex.     

The activation of glycolysis performed by the non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase in the model system

Influence of non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase (GAPN) on glycolysis was investigated. The addition of GAPN-which oxidizes glyceraldehyde-3-phosphate directly to the 3-phosphoglyceric acid-led to the strong increase in the rate of lactate accumulation in the rat muscle extract with low ADP content. The lactate accumulation was also observed in the presence of GAPN in rat muscle extract, which contained only ATP and no ADP. This can be the evidence of the "futile cycle" stimulated by GAPN. Here ADP can be regenerated from ATP by the phosphoglycerate kinase reaction. The high resistance of GAPN from Streptococcus mutans towards inactivation by natural oxidant-H(2)O(2) was showed. This feature distinguishes GAPN from phosphorylating glyceraldehyde-3-phosphate dehydrogenase, which is very sensitive to modification by hydrogen peroxide. A possible role of the oxidants and non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase in the regulation of glycolysis is discussed.     

Evidence for polynuclear aggregates of ferric daunomycin. A M?ssbauer, EPR, X-ray absorption spectroscopy and magnetic susceptibility study.

The interaction of the antitumor agent daunomycin (DN) with ferric iron has been analysed by M?ssbauer spectroscopy, EPR, extended X-ray absorption fine structure (EXAFS), and magnetic susceptibility measurements. In contrast to literature data, at millimolar iron and anthracycline concentrations no solitary Fe(DN)3 complexes are formed in appreciable amounts. The M?ssbauer spectroscopic analysis revealed severe dependencies on temperature, on the preparation procedure, the time allowed for equilibration, and on the metal/ligand ratio. The M?ssbauer spectra exhibit two components: a broad magnetic sextet and a quadrupole doublet at an Fe/DN molar ratio of 1:3 and exclusively a doublet at a molar ratio of 1:20, indicating an equilibrium of these two spectral components. The EPR spectra are dominated by a signal at g(eff) = 2. Double integration of the EPR signals enabled the determination of their spin density and a correlation between EPR and M?ssbauer spectra. The M?ssbauer sextet species is EPR invisible and corresponds to magnetically ordered polynuclear aggregates with high magnetic anisotropy. EXAFS and susceptibility measurements provide additional evidence for the formation of polynuclear aggregates of ferric daunomycin. The quadrupole doublet species in the M?ssbauer spectra correlates with the g = 2 signal in EPR. This species is also related to a magnetically ordered system, exhibiting, however, superparamagnetic behavior due to less magnetic anisotropy. Since daunomycin forms dimers in aqueous solution at millimolar concentrations, we conclude that the cooperative phenomena observed in EPR and M?ssbauer spectra are a consequence of its stacking effects.