The effect of γ-radiation on the hemoglobin of stored red blood cells: the involvement of oxidative stress in hemoglobin conformation.

The aim of the present work was to evaluate the redox and oligomeric effects associated with the human hemoglobin of stored red blood cells that had been previously submitted to gamma radiation. Whole blood was collected from healthy donors and irradiated with 25 Gy of γ-radiation within 24 h of collection. At days 3, 5, 7, 9, 11, 14, and 28 postirradiation, fractions were removed and centrifuged, and the levels of methehemoglobin and oxyhemoglobin were measured. Hb was isolated to measure the denaturation and UV-vis spectra. The results from electrophoresis demonstrated that there was no fragmentation or cross-linking of the hemoglobin. However, ferrous center oxidation was identified as a very significant process. This mechanism is likely through an autoxidation process of the ferrous heme center, which has a maximal intensity between 5 and 7 days of storage. Interestingly, a subsequent reduction of the oxidized heme species was observed, and after 9 days of storage, the difference between the ferric species present in the control and irradiated samples was not representative. This interesting fact suggests a type of "protective action" by the blood to control the oxidative stress generated by the gamma irradiation. The UV-vis measurements demonstrated that the oxidized species was predominantly formed by hemichrome species (bis-histidine ferric heme species), which are usually associated with Heinz bodies. After 28 days of storage, evidence from the UV-vis measurements indicated that the oxidation of the irradiated sample was much higher than that observed in the control sample. These results demonstrate that despite the minimal polypeptide changes observed in the hemoglobin of stored red blood cells after gamma irradiation, the oxidation of the heme metallic center is not irrelevant and must be controlled to improve the hematological clinical procedures associated with the storage of red blood cells.

Heme oxygenase activity causes transient hypersensitivity to oxidative ultraviolet A radiation that depends on release of iron from heme.

Heme oxygenase (HO) breaks down heme to iron, biliverdin, and carbon monoxide, and activity of this enzyme increases in many tissues and cell types after exposure to oxidative stress. There is evidence that increased HO activity is involved in long-term protective mechanisms against oxidative stress. We studied the effect of artificially overexpressed HO activity on the cytotoxicity of oxidative ultraviolet A (UVA) radiation after loading human cells with the HO substrate ferric heme (hemin). In contrast to the reported long-term protection attributed to HO activity, cells overexpressing HO activity were hypersensitive to UVA radiation shortly after heme treatment when compared with control cells. Cells overexpressing HO activity showed an increased rate of heme consumption and a higher level of accumulated free chelatable iron when compared with control cells. The hypersensitivity of cells overexpressing HO to UVA radiation after heme treatment was apparently caused by the increased accumulation of chelatable iron, because the iron chelator desferrioxamine strongly reduced the hypersensitivity. One day after the heme treatment, cells overexpressing HO activity were no longer hypersensitive to UVA radiation. We conclude that increased HO activity can temporarily increase the sensitivity of cells to oxidative stress by releasing iron from heme.

[Nitric oxide, hemoglobin and laser irradiation]. / Oksid azota, gemoglobin i lazernoe obluchenie.

The paper deals with the present views of some chemical properties and biological effects of nitric oxide (NO) and chiefly its formation and primary conversions. The interaction of NO with superoxide radical is shown to one of the most important reactions of the former, which gives rise to peroxynitrite whose breakdown yields a hydroxy radical. Emphasis is laid on the substances that are a temporary depot or a possible transport form of NO, such as nitrosothiols and nitrosyl complexes of non-hemic iron. NO is well-known to release when these compounds are degraded. It is suggested that hemoglobin is another NO depot, which forms stable complexes with the latter. These hemoglobin complexes may be degraded on exposure to laser radiation to form free NO that ha a vasodilatory effect. Photolysis of nitrosyl complexes of hemoglobin may be responsible for the therapeutical effect of laser radiation.

The effect of L-cysteine and N-acetylcysteine on porphyrin/heme biosynthetic pathway in cells treated with 5-aminolevulinic acid and exposed to radiation.

The effects of L-cysteine (LC) and N-acetylcysteine (NAC) on porphyrin accumulation in a human dermal microvascular endothelial cell line (HMEC-1) and a human epidermoid carcinoma cell line (A431) loaded with 5-aminolevulinic acid (ALA) and exposed to ultraviolet A (UVA) and blue light radiation were determined. Porphyrin accumulation was decreased in the presence of 0.1-7.5 mM LC (24.8%-31.4% suppression in HMEC-1 cell; 35.8%-48.9% suppression in A431 cells), and in the presence of 0.1-10.0 mM NAC (30.9%-58.0% suppression in HMEC-1 cells; 8.5%-45.3% in A431 cells). The suppression occurred in a LC or NAC dose-dependent fashion. The above was associated with partial reversal of suppression of ferrochelatase (FeC) activity in HMEC-1 cells and in A431 cells. As compared to FeC activity in cells treated with ALA and irradiation, enzyme activity was higher (by 31.9%-62.1%) in the presence of LC (1.0 mM or 5.0 mM) and in the presence of NAC (1.0 mM or 5.0 mM). These data indicate that LC and NAC have protective effects on porphyrin- and irradiation-induced diminution of FeC activity in HMEC-1 cells and A341 cells in vitro.

The effect of ALA and radiation on porphyrin/heme biosynthesis in endothelial cells.

To study porphyrin biosynthesis in human microvascular endothelial cells, HMEC-1 cells, a transformed human microvascular endothelial cell line, were incubated with 5-aminolevulinic acid (ALA), the precursor of endogenous porphyrins, and porphyrin accumulation was measured spectro-fluorometrically. The HMEC-1 cells accumulated porphyrin in a concentration-related and a time-dependent fashion. Protoporphyrin was the predominant porphyrin accumulated in the cells. The effect of light on protoporphyrin accumulation was evaluated by exposing the ALA-loaded HMEC-1 cells to ultraviolet-A (UVA) and blue light, followed by another incubation with ALA for 2-24 h. Enhancement of protoporphyrin accumulation in irradiated HMEC-1 cells was observed 2-24 h after irradiation, which was associated with a decrease in ferrochelatase protein and activity. Porphyrin accumulation from ALA after irradiation was significantly decreased when catalase (750-3000 U/mL, 29.3-44.3% suppression) or superoxide dismutase (270 U/mL, 36.4% suppression) was present during irradiation. These data demonstrate that HMEC-1 cells were capable of porphyrin biosynthesis, and that exposure of protoporphyrin-containing HMEC-1 cells to UVA and blue light, which includes the Soret band spectrum, decreased the ferrochelatase activity and its protein. These changes were mediated, at least in part, by reactive oxygen species.

Hyperthermia in a differentiating murine erythroleukaemia cell line: II. Effect of heat on haem induction by radiation.

Friend erythroleukaemia cells (FELC) were induced to a haem-producing state by X-rays. The percentage of haem positive cells was maximum for doses between 10 and 15 Gy. Heat treatment at 42.0 degrees C or 45.0 degrees C during or after irradiation inhibited haem induction whereas heating before irradiation enhanced it. Incubation at 37 degrees C between heating and irradiation resulted in a decline in induction levels, indicating repair of heat damage that interacts with X-ray damage. Incubation at 37 degrees C between irradiation and heating did not result in changed haem induction levels, indicating a lack of repair of radiation damage that could interact with subsequent damage produced by heating.

The distribution of the haeme and non-haeme fractions of iron in individual regions of the erythropoietic system of intact and acutely irradiated mice.

In male mice of the strain C57BL/10ScSnPh, both intact and X-irradiated with a whole-body sublethal dose, the distribution of the content of total and haeme iron was studied in individual bones, the spleen, liver, plasma and erythrocytes, using an original mineralization and extraction technique. In the erythropoietic organs as a whole and in the individual bones the haeme and non-haeme iron compartments were distinguished, and within these the iron accounted for by circulating plasma and by erythrocytes and erythrocyte precursors. In the radiation-depleted marrow there were quantitative and qualitative changes in the compartments, particularly the creation of an important compartment of non-circulating (fixed) erythrocytes.

Quantitative radiation effects in hemoproteins and their constituents.

In order to verify the "radiation protection" effect of prosthetic groups in irradiated conjugated proteins and the influence of their electronic structure on intramolecular excitation transfer, two series of substances were examined. The first was composed of ferrihemoglobin and its constituents and the second was composed of similar hemoproteins with heme groups with major differences in electronic structure. The results point to a strong radiation protection effect of the heme groups and a dependence of radical yield of hemoproteins on the electronic structure of the heme. A possible interpretation of this latter effect is discussed.