Effect of physico-chemical factors and species specificity on the structure of dinitrosyl iron complexes

Formation in mouse, rat and man's blood of iron nitrosyl complexes with pair thiol groups of proteins (complexes 2.03) was shown by ESR method. This formation was initiated by the introduction in blood in vitro or in vivo of low molecular dinitrosyl complexes of iron with phosphate, thiosulphate, cysteine or reduced gluthatione. Three forms of these complexes were found. They were characterized by ESR signals with rhombic or axial symmetry of g-factor tensor. These forms pass into one another under the effect of a number of thiol-containing compounds or at blood freezing. The life time of the complexes 2.03 in the blood in vivo is several hours.     

The electron spin resonance and absorption spectra of microsomal cytochrome P-450 and its isocyanide complexes

The absorption spectra of oxidized P-450-isocyanide complexes were the same in difference spectra irrespective of the isocyanide derivative tested. However, with these reduced P-450-isocyanide complexes, absorption at 455 mμ increased, and that at 430 mμ decreased, with increasing carbon atom number of the isocyanide derivative at a definite pH. The same changes were seen with individual complexes with increasing pH.

The dissociation constants of oxidized P-450-isocyanide complexes decreased with increase in carbon atom number of the isocyanide. These results were confirmed by electron spin resonance (ESR) spectroscopy. However, the dissociation constants of reduced P-450-isocyanide complexes were essentially identical and the dissociation constants of the oxidized and reduced P-450-isocyanide complexes were little affected by pH.

The oxidized P-450-isocyanide complexes gave magnetically specific ESR signals. The orbital energy differences of d orbitals of the heme iron of the complexes increased with increase in the carbon atom number of the isocyanide.

Purified P-450 and its isocyanide complexes were rapidly reduced by a ferredoxin-NADP⁺ reductase system.     

Direct observations of the redox states of frozen cherry buds by a unique in vivo ESR

Low temperatures cause cellular damage in flower buds of the sweet cherry (Prunus avium L. cv. Satohnishiki). In this study, the redox states within the cherry buds suffering freezing damage were non-destructively observed by a unique in vivo electron spin resonance (ESR) technique with a spin probe such as carbamoyl-PROXYL. The ESR signals of carbamoyl-PROXYL-treated bud were continuously recorded under freezing and thawing condition, which was decreased to approximately -4 degrees C and maintained for 1.5h, and then returned to room temperature. Most of the buds began to freeze at -2.5 to -3.9 degrees C. The peak areas of the ESR signals significantly increased during the period of temperature rise. These results show that the reduced carbamoyl-PROXYL within the frozen bud was re-oxidized and became ESR-detectable while the bud was thawing. Our in vivo ESR technique has confirmed the oxidative transition of the redox states within the buds during thawing.     

Molecular dynamics in protein-single stranded DNA complexes. Two distinct nucleoside mobilities, in poly(deoxythymidylic acid)-poly-L-lysine complexes

Stoichiometric amounts of poly-L-lysine were added to site-specifically spin labeled single stranded nucleic acids and the resulting complexes analyzed by electron spin resonance spectroscopy (ESR). The nucleic acids were spin labeled to different extents and with labels of varying tether length. The ESR data are used to determine nucleoside dynamics and some structural features in these complexes. It is concluded that two distinct base mobilities exist in the complexes; one set is characterized by a mean correlation time tau -R = 2 ns, and the other one by a tau -R greater than or equal to 50 ns. A model is proposed which suggests that a poly-L-lys single stranded nucleic acid complex consists of low mobility segments flanked by more mobile bases. An interesting feature of the proposed model is its applicability to explain ESR data of single strand binding protein-spin labeled nucleic acid complexes, which can also be interpreted in terms of two distinct nucleoside mobility states. It is hypothesized that this phenomenon could be of biological significance for the release of protein ligands from a protein-nucleic acid complex.     

Effect of metronidazole and local irradiation of the tumor on paramagnetic metal complexes of the liver and tumor tissues

A study was made of changes in the intensity of the ESR signals in tissues of sarcoma-37 and liver of mice after radiation of the tumor, administration of metronidazole, and after the combined effect of the two factors. The most pronounced changes in the ESR signals were induced by metronidazole. An appreciable increase in the content of nitrosyl complexes in the tumor was noted after the combined effect of metronidazole and radiation which was indicative of the radiation-induced formation of a large number of metronidazole anion-radicals in the tumor.     

Transfer of nitric oxide from the liver to erythrocytes--an ESR study using nitroglycerin-treated mice

Nitric oxide (NO) formation in the liver and blood of the mouse following intraperitoneal treatment with nitroglycerin (glycerol trinitrate, GTN) was determined using electron spin resonance (ESR) spectroscopy. ESR signals of heme-NO complexes were detected at maximum levels within 5 min in the liver, but increased to a maximum level about 15-30 min later in the blood. GTN is not metabolized to release NO in vitro in the blood of the mouse. The hepatic microsomes which showed the heme-NO complexes ESR signals were incubated with mouse erythrocytes, with the result that a hemoglobin-NO signal was obtained from the erythrocytes. The activities of microsomal cytochrome P-450, the hepatic level of glutathione, and the reduction rate of nitroxide radicals in the in vivo liver, measured using L-band ESR spectroscopy, were temporarily decreased following GTN administration. In conclusion, NO in the liver could be scavenged by circulating erythrocytes, which might minimize NO-induced liver damage.     

Transfer of nitric oxide from the liver to erythrocytes — An ESR study using nitroglycerin-treated mice

Nitric oxide (NO) formation in the liver and blood of the mouse following intraperitoneal treatment with nitroglycerin (glycerol trinitrate, GTN) was determined using electron spin resonance (ESR) spectroscopy. ESR signals of heme-NO complexes were detected at maximum levels within 5 min in the liver, but increased to a maximum level about 15–30 min later in the blood. GTN is not metabolized to release NO in vitro in the blood of the mouse. The hepatic microsomes which showed the heme-NO complexes ESR signals were incubated with mouse erythrocytes, with the result that a hemoglobin-NO signal was obtained from the erythrocytes. The activities of microsomal cytochrome P-450, the hepatic level of glutathione, and the reduction rate of nitroxide radicals in the in vivo liver, measured using L-band ESR spectroscopy, were temporarily decreased following GTN administration. In conclusion, NO in the liver could be scavenged by circulating erythrocytes, which might minimize NO-induced liver damage.     

Molecular Dynamics in Protein—Single Stranded DNA Complexes. Two Distinct Nucleoside Mobilities in Poly(deoxythymidylic acid)—poly-L-lysine Complexes

Abstract

Stoichiometric amounts of poly-L-lysine were added to site-specifically spin labeled single stranded nucleic acids and the resulting complexes analyzed by electron spin resonance spectroscopy (ESR). The nucleic acids were spin labeled to different extents and with labels of varying tether length. The ESR data are used to determine nucleoside dynamics and some structural features in these complexes. It is concluded that two distinct base mobilities exist in the complexes; one set is characterized by a mean correlation time τR = 2 ns, and the other one by a τR ≤ 50 ns. A model is proposed which suggests that a poly-L-lys single stranded nucleic acid complex consists of low mobility segments flanked by more mobile bases. An interesting feature of the proposed model is its applicability to explain ESR data of single strand binding protein-spin labeled nucleic acid complexes, which can also be interpreted in terms of two distinct nucleoside mobility states. It is hypothesized that this phenomenon could be of biological significance for the release of protein ligands from a protein-nucleic acid complex.     

Structures and electronic properties of the catecholatoiron complexes in relation to catechol dioxygenases: chlorocatecholatoiron complexes are compared to the 3,5-di-tert-butylcatecholatoiron complex in the solid state and in solution

Chlorocatecholatoiron complexes, [Fe(TPA)(4Cl[bond]Cat)]BPh(4) and [Fe(TPA)(3Cl[bond]Cat)]BPh(4), (4Cl[bond]Cat and 3Cl[bond]Cat: 4- and 3-chlorocatecholates, respectively; TPA: tris(2-pyridylmethyl)amine) were isolated as intermediates for the oxygenative cleavage of chlorocatechols by nonheme iron complexes. Geometric structures of these complexes together with [Fe(TPA)(DTBC)]BPh(4) (DTBC: 3,5-di-tert-butylcatecholate) as reference were analyzed by X-ray absorption spectroscopy (EXAFS) in the solid state and in solution. Structure of the DTBC complex in the solid state was shown to be noticeably different from the other complexes as seen in the magnetic susceptibility and spectroscopic data. Electronic and magnetic properties of these complexes were studied by X-ray absorption (XANES), electronic (VIS) and ESR spectroscopies, and magnetic susceptibility. Electron transfer from the catecholate ligand to the Fe(III) center was indicated by the Fe[bond]K edge values in XANES spectra and by the LMCT bands in electronic spectra. Magnetic susceptibility and ESR data indicated that at low temperatures the complexes are in equilibrium between the low (S=1/2) and high-spin (S=5/2) ferric states with the latter component increasing with temperature. Remarkable differences between the spin states in solid and in solution were observed with the DTBC complex.     

An electron spin resonance study on pyrocatechase; the effects of substrate analogues and catechol

Analogues of catechol (protocatechuic acid and ethyl protocatechuate) as well as catechol itself, combine with the enzyme-bound iron of pyrocatechase and formed complexes with the enzyme. The complexes and the native enzyme showed ESR signals characteristic of a ferric iron complex at g=4.3, but the patterns of the signals were different from that of the native enzyme. After forming the complex, ethyl protocatechuate readily released the bound iron of the enzyme protein to give the apoenzyme. The addition of catechol to the enzyme in the absence of oxygen resulted in a decrease of the ESR signal at g=4.3, but which did not disappear. These results indicate that the bound iron of pyrocatechase in the ES complex is similar to ferric iron in a charge transfer complex.     

Iron sources forming nitrosyl complexes in animal tissues

Treatment of perfused mouse liver with nitric oxide does not change the intensities of ESR signals of iron-sulfur proteins characteristic of this tissue. Proceeding from this evidence and also from the ratio between the iron content in these proteins and dinitrosyl iron complexes (complexes 2.03) formed in the liver when it contacts with NO, it is concluded that iron-sulfur proteins are not involved in the formation of complexes 2.03. It seems that only the loosely bound form of non-heme iron-free iron is involved in this process.     

ESR studies of molecular interactions of copper(II) nirvanol and copper(II) diisopropylsalicylate with Ehrlich ascites tumor cells

ESR spectra have been obtained after addition of either a cupric phenylhydantoin or a cupric diisopropylsalicylate complex to Ehrlich ascites tumor cells. It is shown that some of the complex remains in the cupric state. Because the ESR parameters of these complexes in the presence of cells differ from the ESR parameters for these complexes in the absence of cells, in the presence of cells either adducts or new cupric complexes are formed. The fast motion of these complexes, as determined from room temperature ESR spectra, is characteristic of complexes with molecular weights less than 1500.     

Sulfur ligands within the cluster formations of copper at its strong'binding sites on the cytoplasmic membrane of Escherichia coli]

The analysis of the saturation curves of ESR signals revealed a decrease in the relaxation rate of fast-relaxation Cu(I) complexes on the cytoplasmic membrane of E. coli after the interaction of these bacteria with low concentrations of SH-reagents. It was concluded that the observed changes are associated with the reorganization of Cu clusters due to the binding of SH groups incorporated into the clusters N-ethylmaleimide or Ag(I).     

Metallokinetic analysis of disposition of vanadyl complexes as insulin-mimetics in rats using BCM-ESR method

Among vanadium's wide variety of biological functions, its insulin-mimetic effect is the most interesting and important. Recently, the vanadyl ion (+4 oxidation state of vanadium) and its complexes have been shown to normalize the blood glucose levels of streptozotocin-induced diabetic rats (STZ-rats). During our investigations to find more effective and less toxic vanadyl complexes, the vanadyl-methylpicolinate complex (VO-MPA) was found to exhibit higher insulin-mimetic activity and less toxicity than other complexes, as evaluated by both in vitro and in vivo experiments. Electron spin resonance (ESR) is capable of measuring the paramagnetic species in biological samples. We have developed the in vivo blood circulation monitoring-electron spin resonance (BCM-ESR) method to analyze the ESR signals due to stable organic radicals in real time. In the present investigation, we have applied this method to elucidate the relationship between the blood glucose normalizing effect of VO-MPA and the global disposition of paramagnetic vanadyl species. This paper describes the results of vanadyl species in the circulating blood of rats following intravenous administration of vanadyl compounds. ESR spectra due to the presence of vanadyl species were obtained in the circulating blood, and their pharmacokinetic parameters were estimated using compartment models. The results indicate that vanadyl species are distributed considerably to the peripheral tissues, as estimated by BCM-ESR, and eliminated from the body through the urine, as estimated by ESR at 77 K. The exposure of vanadyl species in the blood was found to be enhanced by VO-MPA treatment. Given these results, we concluded that the pharmacokinetic character of vanadyl species is closely related with the structure and antidiabetic activity of the vanadyl compounds.     

Possible role of iron ions in changes in composition of DNA complexes and their magnetic properties in cell cycle processes

A hypothesis on the possible role of iron cations in transformations of nucleoprotein complexes at certain stages of the cell cycle was formulated. The central idea of the hypothesis is the proposition that iron ions provide changes in the composition of complexes formed by phosphate groups of DNA, by substituting effectively the cationic amino groups of organic ligands in these complexes by the mechanism of competitive replacement of ligands. Then iron ions can be removed by changing the charge of iron ions bound to DNA during redox reactions and their transfer to mobile complexes or by the formation and subsequent removal of weakly charged magnetic nanoparticles of ferric oxides. These magnetic nanoparticles may be responsible for the magnetic effects in cells, e.g., broad ESR signals inherent in ferromagnetic systems. These magnetic effects were discovered in DNA preparations and in cell cultures at early stages of cell division by L.A. Blumenfeld and coworkers.     

Unique in vivo applications of spin traps

The ultimate goal of in vivo electron spin resonance (ESR) spin trapping is to provide a window to the characterization and quantification of free radicals with time within living organisms. However, the practical application of in vivo ESR to systems involving reactive oxygen radicals has proven challenging. Some of these limitations relate to instrument sensitivity and particularly to the relative stability of these radicals and their nitrone adducts, as well as toxicity limitations with dosing. Our aim here is to review the strengths and weaknesses of both traditional and in vivo ESR spin trapping and to describe new approaches that couple the strengths of spin trapping with methodologies that promise to overcome some of the problems, in particular that of radical adduct decomposition. The new, complementary techniques include: (i) NMR spin trapping, which monitors new NMR lines resulting from diamagnetic products of radical spin adduct degradation and reduction, (ii) detection of *NO by ESR with dithiocarbamate: Fe(II) "spin trap-like" complexes, (iii) MRI spin trapping, which images the dithiocarbamate: Fe(II)-NO complexes by proton relaxation contrast enhancement, and (iv) the use of ESR to follow the reactions of sulfhydryl groups with dithiol biradical spin labels to form "thiol spin label adducts," for monitoring intracellular redox states of glutathione and other thiols. Although some of these approaches are in their infancy, they show promise of adding to the arsenal of techniques to measure and possibly "image" oxidative stress in living organisms in real time.     

Comparative study of the ESR spectra of normal and regenerating liver tissue in mice

Low temperature ESR spectra of gamma-irradiated samples of mouse liver regenerating after partial hepatectomy were studied. As compared to ESR spectra of gamma-irradiated samples of health animals liver, in regenerating liver samples new ESR signals from paramagnetic centres S(2.0005) and S(2.0025) were revealed; these signals were earlier recorded by the authors in gamma-irradiated samples of hepatoma 22a. It is concluded that the paramagnetic centres S(2.0005) and S(2.0025) are typical of proliferating tissues of different ethiology.     

Primary events in the photosynthetic reaction centre from Rhodopseudomonas spheroides strain R26: Triplet and oxidized states of bacteriochlorophyll and the identification of the primary electron acceptor

ESR studies at approximately 10 °K on the reaction centre complex of the photosynthetic bacterium Rhodopseudomonas spheroides (strain R26), have revealed bacteriochlorophyll triplet states and a component which has an ESR absorption centred at g = 1.82. The triplet-state bacteriochlorophyll is induced only in the light and is only detectable when the reaction-centre bacteriochlorophyll and its primary electron acceptor are reduced; the ESR triplet state signals are composed of both ESR absorption and ESR emission bands. The oxidation-reduction properties of the g = 1.82 component and its flash-induced kinetic behavior in relation to that of P870 are those expected for the primary electron acceptor in bacterial photosynthesis.     

Heme complexes of rabbit hemopexin,human hemopexin and human serum albumin: Electron spin resonance and Mőssbauer spectroscopic studies

The electron spin resonance (ESR) spectra of human and rabbit ferriheme-hemopexin complexes at 30^oK show an ESR absorption characterized by g_x = 1.60, g_y = 2.25 and g_z = 2.86, characteristic of low-spin ferriheme-proteins. The low-spin nature of the heme-iron in heme-hemopexin is corroborated by the observation of nuclear hyperfine splitting in M?ssbauer spectra at 4.2^oK. The similarity of the ESR spectra of ferriheme-hemopexin with those of low-spin cytochromes which coordinate heme via two histidine residues points to a similar coordination mechanism in hemopexin. In contrast, the ESR spectra of the 1:1 and 2:1 complexes of heme with human serum albumin display signals at g = 6.0 and g = 2.0, characteristic of high-spin ferrihemeproteins.     

Appearance of Esr Signals by the Reaction of 3,5-Dibromo-4-Nitrosobenzenesulfonate (Dbnbs) and Non-Radical Biological Components

The reaction of 3,5-dibromo-4-nitrosobenzenesulfonate (DBNBS) with non-radical biological components produced spin adducts with ESR signals. The reactions of DBNBS with Trp, Gly-Trp, Trp-Gly, Pro, Cys and glutathione at pH 7.5 and room temperature for more than 1 hour gave the nitroxyl free radicals with ESR signals, whereas the reactions with other amino acids and bovine serum albumin did not. Among the amino acids and the peptides, Trp and Trp-containing peptides gave the most intense signals. The reactions of DBNBS with unsaturated fatty acids, i.e., linoleic acid and oleic acid, gave weak ESR signals, whereas the reaction with stearic acid did not. While DBNBS gave no ESR signals by the reactions with DNA, nucleosides and nucleobases, it caused strand breaking in supercoiled DNA. DBNBS also gave ESR signals by the reaction with human plasma similar to those from the reaction with Trp. It was suggested that the nitroxyl free radicals were produced by the addition of DBNBS to the amino acids and unsaturated fatty acids followed by oxidation in the presence of DBNBS. Hence, the use of DBNBS spin trap to detect free radicals in systems containing these biological components after long incubation may give misleading results.