Kinetics of metallo-enzymatic paramagnetic centers and free radicals in the rat liver in lung carcinogenesis

Kinetics of the content of nonheme iron-sulphur-containing (iron-sulphur) proteins, free radicals of electron-transport mitochondrial system, as well as of microsome terminal oxidase cytochrome P-450 is studied in the liver of rats at early stages of carcinogenesis and in the process of tumour growth induced by intratracheal administration of various benz(a)pyrene doses. It is found that the content of iron-sulphur proteins increases after the first administration, then it falls against a background of higher concentration of free radicals. A degree of pronounced changes in the content of the studied iron-sulphur proteins correlates with carcinogen dose. The cytochrome P-450 content is lowered for almost the whole period of carcinogen administration. In later periods animals with morphologically determinable pretumour changes exhibit a much higher content of iron-sulphur proteins, somewhat increased concentration of free radicals and a tendency to an increased level of cytochrome P-450. The appearance and growth of malignant tumours is followed by a considerable decrease in the content of iron-sulphur proteins and cytochrome P-450. On the basis of the results obtained it is supposed that the changes in the content of iron-sulphur proteins in the rat liver is the earliest and most pronounced reaction which depends on the benz(a)pyrene dose and may be of prognostic significance.     

Iron-sulfur centers and free radicals of the electron transfer chains of mitochondria in chemical and hormonal carcinogenesis

One of the possible reasons for peculiar features of the tumour cell energetics is discussed. Regular variations in the iron-sulphur protein content in the mitochondrial electron transport chains were shown in models of chemical and hormonal carcinogenesis. A decrease in the content of these proteins in the tumoural tissue is found at early stages of malignant growth against a background of higher concentration of free radicals. Irreversible nature of an iron-sulphur protein decrease was observed in the liver and adrenals of tumour-bearing animals both under development of hormonal genesis tumours and at various stages of chemical carcinogenesis. Coming from the results obtained it is suggested that disturbances in the state of iron-sulphur proteins affect the oxidation phosphorylation efficiency and that modification of compensatory mechanism results in the glycolysis activation, which is a characteristic feature of the tumour cell energetics.     

The circular-dichroic properties of the ''Rieske'' iron-sulphur protein in the mitochondrial ubiquinol: cytochrome c reductase.

We have studied the c.d. spectra of the 'Rieske' iron-sulphur protein isolated from the ubiquinol: cytochrome c reductase (bc1 complex) of bovine heart mitochondria. Both the oxidized and the reduced form of the 'Rieske' protein display a series of well-resolved c.d. features resembling those reported for the 'Rieske'-type iron-sulphur protein purified from the bacterium Thermus thermophilus [Fee, Findling, Yoshida, Hille, Tarr, Hearshen, Dunham, Day, Kent & Münck (1984) J. Biol, Chem. 259, 124-133]. In particular, the difference spectra, reduced minus oxidized, of both proteins have a distinctive negative band at 497 nm. The c.d. features characteristic of the isolated 'Rieske' protein were found in the dichroic spectra of the whole bc1 complex in the region between 450 and 520 nm. The reduction of the enzyme by ascorbate or ubiquinol is accompanied by the formation of a negative band at about 500 nm that corresponds, in all its c.d. properties, to the specific dichroic absorption of the reduced 'Rieske' iron-sulphur protein.     

Nitric oxide-induced bacteriostasis and modification of iron-sulphur proteins in Escherichia coli

The nitric oxide (NO) cytotoxicity has been well documented in bacteria and mammalian cells. However, the underlying mechanism is still not fully understood. Here we report that transient NO exposure effectively inhibits cell growth of Escherichia coli in minimal medium under anaerobic growth conditions and that cell growth is restored when the NO-exposed cells are either supplemented with the branched-chain amino acids (BCAA) anaerobically or returned to aerobic growth conditions. The enzyme activity measurements show that dihydroxyacid dehydratase (IlvD), an iron-sulphur enzyme essential for the BCAA biosynthesis, is completely inactivated in cells by NO with the concomitant formation of the IlvD-bound dinitrosyl iron complex (DNIC). Fractionation of the cell extracts prepared from the NO-exposed cells reveals that a large number of different protein-bound DNICs are formed by NO. While the IlvD-bound DNIC and other protein-bound DNICs are stable in cells under anaerobic growth conditions, they are efficiently repaired under aerobic growth conditions even without new protein synthesis. Additional studies indicate that L-cysteine may have an important role in repairing the NO-modified iron-sulphur proteins in aerobically growing E. coli cells. The results suggest that cellular deficiency to repair the NO-modified iron-sulphur proteins may directly contribute to the NO-induced bacteriostasis under anaerobic conditions.     

Inhibition of nitrogenase by nitrite and nitric oxide in Rhodopseudomonas sphaeroides f. sp. denitrificans

In cells of Rhodopseudomonas sphaeroides f. sp. denitrificans nitrite and nitric oxide, the products of denitrification, inhibit activity of nitrogenase enzyme.Ferredoxin-linked CO₂ fixation, with H₂ as a reductant, was also inhibited by nitrite and NO in denitrifying cells.EPR spectroscopy of cell preparations treated with NO showed that it reacts with non-haem iron-sulphur proteins to form iron-nitrosyl complexes. Nitrite also reacts with these iron-sulphur proteins, but the formation of ironnitrosyl complexes was dependent on the presence of dithionite. Since nitrite is reduced to NO by dithionite it is likely that nitrogenase and CO₂ fixation reactions are inhibited not only by nitrite itself, but also by nitric oxide.Abbreviation DPPH 1,1-diphenyl-2-picrylhydrazyl     

Spectroscopic studies of the nature of the iron clusters in the soluble hydrogenase from Desulfovibrio desulfuricans (strain Norway 4)

57Fe-enriched samples of the soluble hydrogenase from Desulfovibrio desulfuricans (Norway) have been investigated in both the native (oxidized) and the dithionite-reduced states using M?ssbauer spectroscopy. The data clearly show that the iron in this enzyme is predominantly in the form of iron-sulphur clusters which are closely similar to the [4Fe-4S] clusters found in a large number of ferredoxins, such as that from Bacillus stearothermophilus. There appear to be two [4Fe-4S] clusters. The iron-sulphur clusters in the oxidized protein are virtually diamagnetic, as indicated by M?ssbauer, electron spin resonance and magnetic circular dichroic spectroscopy. On reduction by dithionite + methyl viologen, M?ssbauer spectroscopy showed that only 50% of the [4Fe-4S] clusters were reduced. Even reduction with hydrogen up to a pressure of 23 GPa did not reduce the iron-sulphur clusters completely. An ESR signal due to a rapidly relaxing species with g = 2.03, 1.89 was observed in the reduced protein, together with a weaker spectrum from a slower-relaxing species at g = 2.34, 2.12.     

EPR spectroscopy of the iron-sulphur cluster and sirohaem in the dissimilatory sulphite reductase (desulphoviridin) from Desulphovibrio gigas.

Desulphoviridin in the oxidized state showed EPR signals around g = 6, consistent with the sirohaem being in the high-spin ferric state. This was unreactive with sulphite, sulphide or cyanide; but readily reduced by methyl viologen. When the enzyme was treated with Na2S2O4 the sirohaem was slowly reduced and a spectrum of a reduced iron-sulphur cluster at g = 2.07, 1.93, 1.91 appeared over the course of an hour. An intermediate in this reaction was indicated by a free radical signal which appeared within seconds and then gradually disappeared. On treatment with nitrite and reduced methyl viologen, the enzyme gave a spectrum of a nitroxide derivative similar to that seen with plant nitrite reductase. The midpoint reduction potential of the haem was estimated to be -310 mV or less. The iron-sulphur cluster has a very low potential, being only reduced in the presence of free Na2S2O4 around -560 mV. Desulphoviridin can be classed with sirohaem-containing iron-sulphur proteins.     

Biogenesis of iron-sulphur clusters in amitochondriate and apicomplexan protists

During the last 4 years there has been an enormous interest in the question how iron-sulphur ([Fe-S]) clusters, which are essential building blocks for life, are synthesised and assembled into apo-proteins, both in prokaryotes and in eukaryotes. The emerging picture is that the basic mechanism of this pathway has been well conserved during evolution. In yeast and probably all other eukaryotes the mitochondrion is the place where [Fe-S] clusters are synthesised, even for extramitochondrial [Fe-S] cluster-containing proteins, and a number of proteins have been functionally characterised to a certain extent within this pathway. However, almost nothing is known about this aspect in parasitic protists, although recent studies of amitochondriate protists and on the plastid-like organelle of apicomplexan parasites, the apicoplast, have started to change this. In this article I will summarise the current view of [Fe-S] cluster biogenesis in eukaryotes and discuss its implications for amitochondriate protists and for the plastid-like organelle of apicomplexan parasites.     

Isolation, characterization and regulation of expression of the nuclear genes for the core II and Rieske iron-sulphur proteins of the yeast ubiquinol-cytochrome c reductase

Cloning and mapping of the yeast nuclear genes for the core II (Mr 40 000) and Rieske iron-sulphur proteins of the mitochondrial ubiquinol-cytochrome c reductase, and comparison with the genomic regions in nuclear DNA from which they are derived, show that the genes are likely to be present in single copies and that they are not closely linked. They have been reintroduced into yeast cells on multi-copy plasmids and, similar to results obtained for the Mr 11 000 subunit [Van Loon et al., EMBO J. 2 (1983) 1765-1770], increase in the dosage of either gene prompts discoordinate synthesis of the encoded protein. Quantitative analysis of transformants carrying extra copies of the gene for the iron-sulphur protein shows that messenger RNA level, rate of synthesis and steady-state concentration of the protein correlate well with each other. This indicates that its level, in contrast to that of the Mr 11 000 subunit, is only determined by the concentration of its messenger RNA. Over-production of these proteins does not interfere with mitochondrial function as judged from growth rates of transformed cells on non-fermentable media. The excess Mr 40 000 protein is imported into the mitochondrion, showing that import of this subunit is not obligatorily coupled to complex assembly.     

Study of the iron-sulfur center N-2 from NADH-dehydrogenase in different metabolic states of the mitochondria from liver and heart

The structural--equilibrium and nonequilibrium forms of the center N-2 from NADH-dehydrogenase differ in their parametres of the spin-lattice relaxation. The curves of the temperature dependence of the ESR signal intensity become the effective method of the study of the iron-sulphur proteins. The structural nonequilibrium form of the center N-2 was observed in the "4th" metabolic (by Chance) state, but equilibrium form of the center N-2 prevailed in the "3d" state or in the uncoupled state.     

Location and nucleotide sequence of frdB, the gene coding for the iron-sulphur protein subunit of the fumarate reductase of Escherichia coli

The frdB gene, encoding the iron-sulphur protein subunit of fumarate reductase, has been located and its complete nucleotide sequence determined. The identity of the gene was confirmed by protein chemical studies and determination of the NH2-terminal sequence of the FrdB protein. The frdB gene is situated distal to and partially overlapped by frdA which codes for the flavoprotein subunit of the reductase. Its reading frame contains 244 codons and predicts a protein of Mr 27092. In composition, the FrdB protein is strikingly similar to the corresponding subunit of the related flavoenzyme, succinate dehydrogenase. Analysis of the protein's primary structure revealed several features characteristic of iron-sulphur proteins.     

E.P.R. spectra of iron-sulphur proteins in dimethylsulphoxide solutions: evidence that chloroplast photosystem I particles contain 4Fe-4S centres.

A number of iron-sulphur proteins have been shown to undergo reversible changes in structure in 80% dimethylsulphoxide solution. EPR¹spectra of the reduced proteins in this state show characteristic lineshapes and temperature dependence, according to whether the centres are of the 2Fe2S or 4Fe4S type. EPR spectra of Photosystem I particles from spinach chloroplasts, reduced in 80% dimethylsulphoxide, indicate the presence of 4Fe4S centres. The integrated intensity of these signals is consistent with their having arisen from the membrane-bound iron-sulphur proteins of Photosystem I.     

Probing the mechanism of rubredoxin thermal unfolding in the absence of salt bridges by temperature jump experiments

Rubredoxins are the simplest type of iron-sulphur proteins and in recent years they have been used as model systems in protein folding and stability studies, especially the proteins from thermophilic sources. Here, we report our studies on the rubredoxin from the hyperthermophile Methanococcus jannaschii (T opt = 85 degrees C), which was investigated in respect to its thermal unfolding kinetics by temperature jump experiments. Different spectroscopic probes were used to monitor distinct structural protein features during the thermal transition: the integrity of the iron-sulphur centre was monitored by visible absorption spectroscopy, whereas tertiary structure was followed by intrinsic tryptophan fluorescence and exposure of protein hydrophobic patches was sensed by 1-anilinonaphthalene-8-sulphonate fluorescence. The studies were performed at acidic pH conditions in which any stabilising contributions from salt bridges are annulled due to protonation of protein side chain groups. In these conditions, M. jannaschii rubredoxin assumes a native-like, albeit more flexible and open conformation, as indicated by a red shift in the tryptophan emission maximum and 1-anilinonaphthalene-8-sulphonate binding. Temperature jumps were monitored by the three distinct techniques and showed that the protein undergoes thermal denaturation via a simple two step mechanism, as loss of tertiary structure, hydrophobic collapse, and disintegration of the iron-sulphur centre are concomitant processes. The proposed mechanism is framed with the multiphasic one proposed for Pyrococcus furiosus rubredoxin, showing that a common thermal unfolding mechanism is not observed between these two closely related thermophilic rubredoxins.     

Iron-sulphur cluster biogenesis and mitochondrial iron homeostasis

Iron-sulphur clusters are important cofactors for proteins that are involved in many cellular processes, including electron transport, enzymatic catalysis and regulation. The enzymes that catalyse the formation of iron-sulphur clusters are widely conserved from bacteria to humans. Recent studies in model systems and humans reveal that iron-sulphur proteins have important roles in mitochondrial iron homeostasis and in the pathogenesis of the human disease Friedreich ataxia.     

Correlation of nuclear acceptor sites for oestrogen receptors with gene transcription in vitro

1. Membrane particles prepared from ultrasonically-disrupted, aerobically-grown Escherichia coli were centrifuged on to a plastic film that was supported perpendicular to the centrifugal field to yield oriented membrane multilayers. In such preparations, there is a high degree of orientation of the planes of the membranes such that they lie parallel to each other and to the supporting film. 2. When dithionite- or succinate-reduced multilayers are rotated in the magnetic field of an e.p.r. spectrometer, about an axis lying in the membrane plane, angular-dependent signals from an iron-sulphur cluster at g(x)=1.92, g(y)=1.93 and g(z)=2.02 are seen. The g=1.93 signal has maximal amplitude when the plane of the multilayer is perpendicular to the magnetic field. Conversely, the g=2.02 signal is maximal when the plane of the multilayer is parallel with the magnetic field. 3. Computer simulations of the experimental data show that the cluster lies in the cytoplasmic membrane with the g(y) axis perpendicular to the membrane plane and with the g(x) and g(z) axes lying in the membrane plane. 4. In partially-oxidized multilayers, a signal resembling the mitochondrial high-potential iron-sulphur protein (Hipip) is seen whose g(z)=2.02 axis may be deduced as lying perpendicular to the membrane plane. 5. Appropriate choice of sample temperature and receiver gain reveals two further signals in partially-reduced multilayers: a g=2.09 signal arises from a cluster with its g(z) axis in the membrane plane, whereas a g=2.04 signal is from a cluster with the g(z) axis lying along the membrane normal. 6. Membrane particles from a glucose-grown, haem-deficient mutant contain dramatically-lowered levels of cytochromes and exhibit, in addition to the iron-sulphur clusters seen in the parental strain, a major signal at g=1.90. 7. Only the latter may be demonstrated to be oriented in multilayer preparations from the mutant. 8. Comparisons are drawn between the orientations of the iron-sulphur proteins in the cytoplasmic membrane of E. coli and those in mitochondrial membranes. The effects of diminished cytochrome content on the properties of the iron-sulphur proteins are discussed.     

Carboxymethylation of methionine residues in bovine pituitary luteinizing hormone and its subunits. Effects on the binding activity with receptor sites and interactions between subunits.

The properties of the component 'X' identified as the primary electron acceptor of Photosystem I in spinach was investigated by electron-paramagnetic-resonance spectroscopy and the complete spectrum obtained for the first time. Component 'X' has gx = 1.78, gy = 1.88 and gz = 2.08; it can be observed only at very low temperatures (8--13K) and high microwave powers. Component X was identified in Photosystem I particles prepared with the French press or with Triton X-100. In samples reduced with ascorbate, illumination at low temperatures results in the photo-oxidation of P700 and reduction of a bound iron-sulphur protein; this is irreversible at low temperature. In samples in which the iron-sulphur proteins are reduced by sodium dithionite, illumination at low temperature results in the oxidation of P700 and the reduction of component 'X'; this is reversible at low temperature. The light-induced P700 signal is the same size with either ascorbate or dithionite as reducing agent, showing that all of the P700 involved in reduction of bound ferredoxin also functions in the reduction of component 'X'.