Polynuclear water-soluble dinitrosyl iron complexes with cysteine or glutathione ligands: Electron paramagnetic resonance and optical studies

Electron paramagnetic resonance and optical spectrophotometric studies have demonstrated that low-molecular dinitrosyl iron complexes (DNICs) with cysteine or glutathione exist in aqueous solutions in the form of paramagnetic mononuclear (М-DNICs) and diamagnetic binuclear complexes (B-DNICs). The latter represent Roussin’s red salt esters and can be prepared by treatment of aqueous solutions of Fe²⁺ and thiols (рН 7.4) with gaseous nitric oxide (NO) at the thiol:Fe²⁺ ratio 1:1. М-DNICs are synthesized under identical conditions at the thiol:Fe²⁺ ratios above 20 and produce an EPR signal with an electronic configuration {Fe(NO)₂}⁷ at g_aver. = 2.03. At neutral pH, aqueous solutions contain both M-DNICs and B-DNICs (the content of the latter makes up to 50% of the total DNIC pool). The concentration of B-DNICs decreases with a rise in pH; at рН 9–10, the solutions contain predominantly M-DNICs. The addition of thiol excess to aqueous solutions of B-DNICs synthesized at the thiol:Fe²⁺ ratio 1:2 results in their conversion into М-DNICs, the total amount of iron incorporated into M-DNICs not exceeding 50% of the total iron pool in B-DNICs. Air bubbling of cys-М-DNIC solutions results in cysteine oxidation-controlled conversion of М-DNICs first into cys-B-DNICs and then into the EPR-silent compound Х able to generate a strong absorption band at 278 nm. In the presence of glutathione or cysteine excess, compound Х is converted into B-DNIC/M-DNIC and is completely decomposed under effect of the Fe²⁺ chelator о-phenanthroline or N-methyl-d-glucamine dithiocarbamate (MGD). Moreover, MGD initiates the synthesis of paramagnetic mononitrosyl iron complexes with MGD. It is hypothesized that compound Х represents a polynuclear DNIC with cysteine, most probably, an appropriate Roussin’s black salt thioesters and cannot be prepared by simple substitution of М-DNIC cysteine for glutathione. Treatment of М-DNIC with sodium dithionite attenuates the EPR signal at g_aver. = 2.03 and stimulates the appearance of an EPR signal at g_aver. = 2.0 with a hypothetical electronic configuration {Fe(NO)₂}⁹. These changes can be reversed by storage of DNIC solutions in atmospheric air. The EPR signal at g_aver. = 2.0 generated upon treatment of B-DNICs with dithionite also disappears after incubation of B-DNIC solutions in air. In all probability, the center responsible for this EPR signal represents М-DNIC formed in a small amount during dithionite-induced decomposition of B-DNIC.     

Dinitrosyl iron complexes with thiolate ligands: Physico-chemistry,biochemistry and physiology

Some present-day concepts on the origin and functional activities of dinitrosyl iron complexes (DNIC) with thiolate ligands are considered. Nitric oxide (NO) including to DNIC increases its stability and ensures effective targeting of NO to organs and tissues. DNIC have a square–planar structure; unpaired electron is localized on the d_z2 orbital of the d⁷ iron atom. The formula of DNIC appears as {(RS^?)₂Fe⁺(NO⁺)₂….(^?SR)₂}^?; electron spin is S = 1/2. Conversion of an originally diamagnetic group, Fe²⁺(NO)₂ with electron configuration d⁸, into a paramagnetic Fe⁺(NO⁺)₂ group is a result of disproportionation of NO ligands and substitution of newly generated NO^? for NO. The nitrosonium ions present in DNIC impart to them high nitrosylating activity, e.g., ability to induce S-nitrosylation of thiols. The ability of S-nitrosothiols to form DNIC in a direct reaction with bivalent iron is a prerequisite to effective mutual conversions of DNIC and S-nitrosothiols. In this work, I consider some mechanisms of destructive effects of low-molecular DNIC on active centers of iron–sulfur proteins, ability of DNIC to express certain genes, to activate guanylate cyclase, to exert hypotensive, vasodilator effects, to inhibit platelet aggregation, to accelerate wound healing and to produce potent erective action. Recently a stabilized powder-like polymeric composition based on dimeric glutathione DNIC the water-soluble polymer in which was used as a filling agent was designed. The advantages of this stable DNIC-glutathione preparation include their ability to retain their physico-chemical and functional activities within at least one year. At present, the preparation undergo testing as a base for the design of a wide variety of broad-spectrum drugs.     

Evidence for the interaction of the Photosystem I secondary electron acceptor X with chlorophyll a in spinach Photosystem I particles

Ether extraction of antenna pigments from PS I particles (Ikegami, I. and Katoh, S. (1975) Biochim. Biophys. Acta 376, 588–592) led to the change of EPR signal of the PS I secondary electron acceptor ‘X’. The g_x value of the EPR signal of X, which was 1.77 in the PS I particles, remained unchanged as far as the pigment extracted was less than 50%. However, further extraction of pigments shifted it to the higher value; it came up to 1.80 in the particles containing about 5% chlorophyll a. g_y and g_z values of the EPR signal of X were less sensitive to the pigment extraction. The g_x signal intensity of the EPR signal of X remained almost constant through the pigment extraction. The re-incorporation of the purified chlorophyll a to the pigment-extracted particles resulted in a partial recovery of the g_x value. On the other hand, vitamin K-1 had no significant effect on the recovery of the g_x value. The results suggest the close location of the component X to chlorophyll a in the vicinity of PS I reaction center.     

EPR detection of a cryogenically photogenerated intermediate in photosynthetic oxygen evolution

In Photosystem II preparations at low temperature we were able to generate and trap an intermediate state between the S₁ and S₂ states of the Kok scheme for photosynthetic oxygen evolution. Illumination of dark-adapted, oxygen-evolving Photosystem II preparations at 140 K produces a 320-G-wide EPR signal centered near g = 4.1 when observed at 10 K. This signal is superimposed on a 5-fold larger and somewhat narrower background signal; hence, it is best observed in difference spectra. Warming of illuminated samples to 190 K in the dark results in the disappearance of the light-induced g = 4.1 feature and the appearance of the multiline EPR signal associated with the S₂ state. Low-temperature illumination of samples prepared in the S₂ state does not produce the g = 4.1 signal. Inhibition of oxygen evolution by incubation of PS II preparations in 0.8 M NaCl buffer or by the addition of 400 μM NH₂OH prevents the formation of the g = 4.1 signal. Samples in which oxygen evolution is inhibited by replacement of Cl^? with F^? exhibit the g = 4.1 signal when illuminated at 140 K, but subsequent warming to 190 K neither depletes the amplitude of this signal nor produces the multiline signal. The broad signal at g = 4.1 is typical for a $\text{S =}\text{5}\text{2}$ spin system in a rhombic environment, suggesting the involvement of non-heme Fe in photosynthetic oxygen evolution.     

EPR studies of the water oxidizing complex in the S1 and the higher S states: the manganese cluster and YZ radical

The parallel polarization electron paramagnetic resonance (EPR) method has been applied to investigate manganese EPR signals of native S₁ and S₃ states of the water oxidizing complex (WOC) in photosystem (PS) II. The EPR signals in both states were assigned to thermally excited states with S=1, from which zero-field interaction parameters D and E were derived. Three kinds of signals, the doublet signal, the singlet-like signal and g=11–15 signal, were detected in Ca²⁺-depleted PS II. The g=11–15 signal was observed by parallel and perpendicular modes and assigned to a higher oxidation state beyond S₂ in Ca²⁺-depleted PS II. The singlet-like signal was associated with the g=11–15 signal but not with the Y_Z (the tyrosine residue 161 of the D1 polypeptide in PS II) radical. The doublet signal was associated with the Y_Z radical as proved by pulsed electron nuclear double resonance (ENDOR) and ENDOR-induced EPR. The electron transfer mechanism relevant to the role of Y_Z radical was discussed.     

A new EPR signal attributed to the primary plastosemiquinone acceptor in Photosystem II

A study of signals, light-induced at 77 K in O₂-evolving Photosystem II (PS II) membranes showed that the EPR signal that has been attributed to the semiquinone-iron form of the primary quinone acceptor, Q^?_AFe, at g = 1.82 was usually accompanied by a broad signal at g = 1.90. In some preparations, the usual g = 1.82 signal was almost completely absent, while the intensity of the g = 1.90 signal was significantly increased. The g = 1.90 signal is attributed to a second EPR form of the primary semiquinone-iron acceptor of PS II on the basis of the following evidence. (1) The signal is chemically and photochemically induced under the same conditions as the usual g = 1.82 signal. (2) The extent of the signal induced by the addition of chemical reducing agents is the same as that photochemically induced by illumination at 77 K. (3) When the g = 1.82 signal is absent and instead the g = 1.90 signal is present, illumination at 200 K of a sample containing a reducing agent results in formation of the characteristic split pheophytin^? signal, which is thought to arise from an interaction between the photoreduced pheophytin acceptor and the semiquinone-iron complex. (4) Both the g = 1.82 and g = 1.90 signals disappear when illumination is given at room temperature in the presence of a reducing agent. This is thought to be due to a reduction of the semiquinone to the nonparamagnetic quinol form. (5) Both the g = 1.90 and g = 1.82 signals are affected by herbicides which block electron transfer between the primary and secondary quinone acceptors. It was found that increasing the pH results in an increase of the g = 1.90 form, while lowering the pH favours the g = 1.82 form. The change from the g = 1.82 form to the g = 1.90 form is accompanied by a splitting change in the split pheophytin^? signal from approx. 42 to approx. 50 G. Results using chloroplasts suggest that the g = 1.90 signal could represent the form present in vivo.     

EPR studies of the oxygen-evolving enzyme of Photosystem II

The light-induced EPR multiline signal is studied in O₂-evolving PS II membranes. The following results are reported: (1) Its amplitude is shown to oscillate with a period of 4, with respect to the number of flashes given at room temperature (maxima on the first and fifth flashes). (2) Glycerol enhances the signal intensity. This effect is shown to come from changes in relaxation properties rather than an increase in spin concentration. (3) Deactivation experiments clearly indicate an association with the S₂ state of the water-oxidizing enzyme. A signal at g = 4.1 with a linewidth of 360 G is also reported and it is suggested that this arises from an intermediate donor between the S states and the reaction centre. This suggestion is based on the following observations: (1) The g = 4.1 signal is formed by illumination at 200 K and not by flash excitation at room temperature, suggesting that it arises from an intermediate unstable under physiological conditions. (2) The formation of the g = 4.1 signal at 200 K does not occur in the presence of DCMU, indicating that more than one turnover is required for its maximum formation. (3) The g = 4.1 signal decreases in the dark at 220 K probably by recombination with Q^?_AFe. This recombination occurs before the multiline signal decreases, indicating that the g = 4.1 species is less stable than S₂. (4) At short times, the decay of the g = 4.1 signal corresponds with a slight increase in the multiline S₂ signal, suggesting that the loss of the g = 4.1 signal results in the disappearance of a magnetic interaction which diminishes the multiline signal intensity. (5) Tris-washed PS II membranes illuminated at 200 K do not exhibit the signal.     

The Origin of the Multiline and g = 4.1 Electron Paramagnetic Resonance Signals from the Oxygen-Evolving System of Photosystem II

Continuous illumination at 200 K of photosystem (PS) II-enriched membranes generates two electron paramagnetic resonance (EPR) signals that both are connected with the S₂ state: a multiline signal at g 2 and a single line at g = 4.1. From measurements at three different X-band frequencies and at 34 GHz, the g tensor of the multiline species was found to be isotropic with g = 1.982. It has an excited spin multiplet at ~30 cm^-1, inferred from the temperature-dependence of the linewidth. The intensity ratio of the g = 4.1 signal to the multiline signal was found to be almost constant from 5 to 23 K. Based on these findings and on spin quantitation of the two signals in samples with and without 4% ethanol, it is concluded that they arise from the ground doublets of paramagnetic species in different PS II centers. It is suggested that the two signals originate from separate PS II electron donors that are in a redox equilibrium with each other in the S₂ state and that the g = 4.1 signal arises from monomeric Mn(IV).     

On the nature of the g = 6 EPR signal in isolated cytochrome b6f complex from spinach chloroplasts

Cytochrome b₆ in freshly prepared, active cytochrome t₆f complex from spinach chloroplasts shows a broad, low-spin EPR signal around g_z = 3.6. Maximally half of the hemes of cytochrome b₆ can be changed to high spin with a signal at g = 6 by inactivating treatments, or by isolating cytochrome b₆. In this state the heme reacts with NO. Reduction rates suggest that it is the low-potential heme which changes. The change is accompanied by the loss of the shift in the g_y signal of the Rieske FeS-center by quinone analogs.     

Electron paramagnetic resonance spectra of mitochondrial and microsomal cytochrome P-450 from the rat adrenal

The electron paramagnetic resonance (EPR) spectra of rat adrenal zona fasciculata mitochondria showed peaks corresponding to low spin ferric cytochrome P-450 with apparent g values of 2.424, 2.248 and 1.917, and weak signals due to high spin ferric cytochrome P-450 with g_x values of 8.08 and 7.80. The former is attributed to cholesterol side chain cleavage cytochrome P-450, the latter to 11β-hydroxylase cytochrome P-450. On addition of deoxycorticosterone the g = 7.80 signal was elevated and there was an associated drop in the low spin signal. As the pH was reduced from 7.4 to 6.1, the g = 8.08 signal increased with again a drop in intensity of the low spin signal. Mitochondria from the zona glomerulosa showed similar spectral properties to those described above. Addition of succinate, isocitrate or pregnenolone caused a loss of the g = 8.08 signal. Addition of calcium increased the magnitude of the g = 8.08 signal, and caused a slight reduction in the magnitude of the low spin signal. Also, addition of deoxycorticosterone, pregnenolone, succinate or isocitrate caused slight shifts of the outer lines of the low spin spectrum. Interaction of mitochondrial cytochrome P-450 with metyrapone and aminoglutethimide modified the low spin parameters. Adrenal microsomal cytochrome P-450 had low spin ferric g values of 2.417, 2.244 and 1.919 and high spin ferric g_xy values of 7.90 and 3.85, distinct from the values obtained with mitochondria.     

Biochemical and biophysical studies on cytochrome c oxidase. XVII. An epr study of the photodissociation of cytochrome a32+ · CO

1. The photodissociation reaction of the cytochrome c oxidase-CO compound was studied by EPR at 15 °K. Illumination with white light at both room and liquid N₂ temperatures of the partially reduced cytochrome c oxidase (2 electrons per 4 metals) in the presence of CO, causes the appearance of a rhombic (g_x = 6.60, g_y = 5.37) high-spin heme signal.This signal disappears completely upon darkening of the sample and reappears upon illumination at room temperature; accordingly the photolytic process is reversible. Under these conditions, no great changes in the intensities are observed, neither of the copper signal at g = 2, nor of the low-spin heme signal at g = 3, 2.2 and 1.5.2. In the presence of ferricyanide (2 mM) and CO, both the low-spin heme signal (g = 3.0, 2.2 and 1.5) and the copper signal of the partially reduced enzyme have intensities about equal to those of the completely oxidized enzyme in the absence of CO. Upon illumination of the carboxy-cytochrome c oxidase in the presence of ferricyanide, it was found that the rhombic high-spin heme signal appears without affecting appreciably the copper of low-spin heme signals. Thus, in the presence of ferricyanide the EPR-detectable paramagnetism of the illuminated carboxy-cytochrome c oxidase is higher than in the untreated oxidized enzyme.3. The membrane-bound cytochrome c oxidase reduced with NADH in the presence of CO and subsequently oxidized with ferricyanide shows a similar rhombic high-spin heme signal (g_x = 6.62, g_y = 5.29) upon illumination at room temperature. This signal disappears completely upon darkening and reappears upon illumination at room temperature.     

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).     

An EPR Study of NO Bonding to Erythrocruorin from the Earthworm Octolasium Complanatum

The EPR properties of the nitric oxide derivative of Octolasium complanatum erythrocruorin have been investigated as a function of the concentration of protons and cations which are known to affect the oxygen-linked allosteric equilibrium. The EPR spectrum has a rhombic shape with g_x = 2.08, g_z = 2.005, and g_y = 1.99, and remains unchanged under all the experimental conditions used. A supernyperfine pattern consisting of nine equally spaced lines is present in the g_z region indicating an interaction with two nonequivalent nitrogen atoms, one contributed by the nitric oxide and the other by the proximal histidine. The constancy of the EPR spectrum suggests that changes in the allosteric equilibrium do not involve differences in the strain of the Fe(II)-histidine bond as in tetrameric hemoglobins.     

The iron-quinone acceptor complex in Rhodospirillum rubrum chromatophores studied by EPR

A new EPR signal is reported in Rhodospirillum rubrum chromatophores. The signal is attributed to Q⁻_BFe²⁺, the semiquinone-iron complex of the secondary quinone electron acceptor, on the basis of the following observations. (1) It is induced by a single laser flash given a room temperature and is stable. (2) It is present after odd-numbered flashes and absent after even-numbered flashes when a series of flashes is given. (3) When it is already present, low-temperature illumination results in the disappearance of the signal due to formation of the Q⁻_AFe²⁺Q⁻_B state. (4) Its formation is inhibited by the presence of orthophenanthroline at normal values of pH. The Q⁻_BFe²⁺ signal has two main features, one at g = 1.93 and the other at g = 1.82. The two features have different microwave power and temperature dependences, with the g = 1.82 signal being more difficult to saturate and requiring lower temperatures to be observable. Raising the pH leads to an increase in the g = 1.82 feature, while the g = 1.93 signal decreases in amplitude. It is suggested that the two parts of the signal may represent two EPR forms due to structural heterogeneity. The low-field feature of the Q⁻_BFe²⁺ signal shifts to lower field as the pH is raised and a pK for this change seems to occur at pH 9.4. The Q⁻_AFe²⁺ signal at g = 1.88 also shifts as the pH is increased; however, the shift is less marked than that seen for Q⁻_BFe²⁺, the shift is to higher field and the range over which it occurs is wider and depends upon the temperature of Q⁻_AFe²⁺ formation. This effect may be due to a pK on a protein group being shifted to higher pH by the presence of Q⁻_A. ortho-Phenanthroline broadens and shifts the Q⁻_AFe²⁺ signal. The inhibition of electron transfer between Q⁻_A and Q_B by ortho-phenanthroline becomes less effective at high pH. The new Q⁻_BFe²⁺ signal is unlike other semiquinone-iron signals reported in the literature in bacteria; however, it is remarkably similar to the Q⁻_BFe²⁺ signal reported in Photosystem II.     

Effects of trypsin upon EPR signals arising from components of the donor side of Photosystem II

EPR signals from components functioning on the electron donor side of Photosystem II (PS II) have been monitored in PS II membranes isolated from spinach chloroplasts after treatment with trypsin at pH 7.5 and pH 6.0. The following information has been obtained. (1) The multiline manganese signal, the g = 4.1 signal and Signal II_slow are lost with trypsin treatment at pH 7.5, but not at pH 6.0. (2) At pH 7.5 the multiline S₂ signal and the g = 4.1 signal are lost with approximately the same dependency on the incubation time with trypsin. At pH 6.0 trypsin treatment is known to block electron transfer between Q_A and Q_B (the first and the second quinone electron acceptors, respectively) allowing only a single turnover to occur. Under these conditions both the g = 4.1 signal and the multiline signal are induced by illumination at 200 K and their amplitudes are almost the same as in untreated samples. These results are interpreted as indicating that the g = 4.1 signal arises from a side path donor or from S₂ itself rather than a carrier functioning between the S states and the reaction center as previously suggested. (3) Cytochrome b-559 is converted to its oxidized low-potential form by trypsin treatment at both values of pH. At pH 6.0 the S-state turnover still occurs indicating that the presence of reduced high-potential cytochrome b-559 is not necessary for this process.     

Dinitrosyl iron complexes with cysteine suppress the development of experimental endometriosis in rats

Administration of dinitrosyl iron complexes (DNIC) with cysteine suppressed the development of experimental (surgically induced) endometriosis in rats: the mean size of endometrioma was 1.85 times smaller if 0.5 mL of a 5 mM aqueous solution of DNIC had been injected daily for 10 days. It is supposed that NO molecules and nitrosonium ions (NO⁺), released from DNIC rapidly decomposed in the organism, prove cytotoxic for endometrioid tissue.     

Electron paramagnetic resonance studies on nitrogenase. II. Interaction of adenosine 5′-triphosphate with azoferredoxin

The interaction of ATP with both iron-sulfur proteins of nitrogenase from Clostridium pasteurianum, azoferredoxin and molybdoferredoxin, has been studied by low-temperature EPR spectroscopy. ATP in the presence of Mg²⁺ changes the rhombic EPR signal of azoferredoxin with g-values of 2.06, 1.94 and 1.87 to an axial signal, with g values of 2.04 and 1.93. The binding of two molecules of ATP per azoferredoxin dimer (mol. wt 55 000) is suggested. Comparative data with other purine and pyrimidine nucleotides and ATP analogues demonstrate the involvement of structural elements of the substrate in the conversion of the EPR signal of azoferredoxin. A similar effect is induced by 5 M urea, which suggests that ATP causes a conformation change of the protein. In contrast, no effect of ATP was observed on the EPR signal of molybdoferredoxin.     

Cardioprotective efficacy of dinitrosyl iron complex with L-cysteine in rats in vivo

The effect of dinitrosyl iron complex (DNIC) with L-cysteine on the hemodynamic indices and the size of myocardial infarction, which was induced by 40-min regional ischemia and subsequent 60-min reperfusion, have been studied in rats in vivo. Intravenous bolus injection of DNIC (3.1 μmol/kg body weight in 0.5 ml saline) was performed before regional ischemia; the control group was administered the same volume of saline. DNIC administration significantly decreased the mean blood pressure throughout the experiment. DNIC reduced the duration of cardiac arrhythmias to 170 ± 10 s as against 445 ± 30 s in control. The myocardial infraction size significantly decreased in the DNIC group compared to control (38.0 ± 1.4 and 48.0 ± 3.9% of the area at risk, respectively; p < 0.05). A combination of the vasodilatory effect of DNIC with the reduction of the damaging effect of cardiac ischemia and reperfusion encourage the development of hypotensive and antiischemic drugs on this class of NO donors.     

EPR study of iron status in human body during intensive physical activity

The iron metabolism was studied in serum blood samples collected from 26 professional sportsmen undergoing intensive physical exercises using EPR combined with hematological and biochemical laboratory tests. Only 23% of EPR spectra (n = 6) were practically normal while in the rest spectra additional abnormal absorption lines were detected. Presumably, the significant portion of new signals may be caused by different cytochromes. Moreover, the anisotropic signals with g ₁ ? 2.02; g ₂ ? 1.94 and g ₃ ? 1.86 registered in some spectra pointed to the sulfur-iron centers. There was nearly linear correlation between the concentration of Fe³⁺ in transferrin (Fe³⁺-Tf) obtained from the EPR spectra and the serum iron concentration measured by absorption photometry both for sportsmen and controls (healthy individuals and patients with different diseases). At equal serum iron concentrations the Fe³⁺-Tf level was higher in sportsmen than that in controls. The Pearson correlation coefficient (r) for Fe³⁺-Tf and serum iron values was equal to 0.89 in sportsmen versus r = 0.97 in controls. Additional new lines in serum EPR spectra of professional sportsmen prove the suitability of EPR assay for scheduled medical exams since routine biochemical and hematological tests are insufficient to discover all abnormalities in iron metabolism under intensive physical exercises.