Mechanism of the radioprotective effect of cysteamine

The radioprotective effect of cysteamine combined with the modification of the chromatin state by sodium butyrate has been studied using V-79 and CHEL lines of Chinese hamster cells and HeLa cells. Sodium butyrate enhances the chromatin sensitivity to nucleases and removes the radioprotective effect of cysteamine as measured by the yield of cells with chromosome aberrations. As is indicated by changes in the intensity of fluorescence of the DNA-ethidium bromide complex, measured by laser flow cytometry, the protective agent decreases the binding of the dye with both irradiated and nonirradiated DNA whereas ionizing radiation and sodium butyrate increase thereof. It is concluded that the radioprotective effect of cysteamine depends in its ability to reduce the susceptibility of DNA to nucleases.     

Postradiation effect of a radioprotector depending on the degree of chromatin condensation in the cells

It was shown on HeLa cells synchronized in mitosis and on rat liver hepatocytes in G0 stage that cysteamine administered after gamma-irradiation produced the radioprotective effect which was not observed in hepatocytes in G1 stage.     

The induction of hepatocyte polyploidization in rats of various ages by ionizing irradiation with different LETs

A decrease in the effectiveness of neutron-irradiation with respect to fusion of nonproliferating hepatocytes of animals with age was shown by the method of flow cytometry. There was an inverse relationship between the effectiveness of induction of nonproliferating hepatocytes fusion and neutron energy. The process of hepatocyte fusion induced by neutrons was inhibited by uranyl acetate. No age-dependent changes were noted in the induction of polyploidization of proliferating hepatocytes by sparsely ionizing radiation. A hypothesis is proposed concerning a membrane nature of the target responsible for hepatocyte polyploidization induced by densely ionizing radiation.     

Polyploidization of rat hepatocytes induced by x-ray radiation at different periods of the cell cycle

As determined by the yield of polyploid hepatocytes after X-irradiation of rats with a dose of 6 Gy the S-stage of the cell cycle was most radiosensitive; as to the yield of cells with chromosome aberrations the middle of the G1-stage was the most radiosensitive period of the cell cycle. The differences in the radiosensitivity of the cell cycle stages indicated that although primary lesions were similar molecular mechanisms leading to tre final effect were essentially different.     

Modification of cellular radiosensitivity by NO-synthase inhibitors

We recently reported that the treatment of V-79 and HeLa cells with nitric oxide synthase (NOS) inhibitor N-nitro-L-arginine methyl ester (L-NAME) significantly reduced the level of the radiation-induced unstable chromosome aberrations. The stereoisomer D-NAME had no effect.We suggest that the radioprotective effect of L-NAME resulted from the action on the generation reactive radicals due to the inhibition of the NOS-activity. We tested this suggestion on the NO-resistant (ECV-304) and NO-sensitive (HeLa) cells, which were treated with L-NAME or aminoguanidine or D-NAME or cysteamine before gamma-irradiation. There are no significantly differences in radiosensitivity between these cells estimated after exposure by gamma-rays with different doses. However, the radioprotective effect of the NOS-inhibitors manifested only for HeLa. D-NAME had no radioprotective effect neither HeLa nor ECV-304. In contrast NOS-inhibitors, cysteamine treatment EVC-304 reduced the radiation-induced level chromosome aberrations almost twofold. The different mechanisms of the modification of cellular radiosensitivity are discussed.     

The blocking of the proliferation of the human endothelial cells in culture by beta-irradiation from internal and external sources of the radiation. S-block is induced by the 3H2O beta-particles

Recently we shown that low doses (0.12-0.46 Gy) of (methyl-3H)-thymidine incorporated into human endothelial cells induce the accumulation cells in G2-phase of the cell cycle. The temperate doses of (1-6 Gy) gamma-rays 137Cs were less effective in the induction of the G2-block estimated by flow cytometry analysis of DNA content and in the induction of the chromosome aberrations (bridges and fragments in anaphase). The aim of this study was the comparative investigation of efficiency of beta-rays emitted 3H from 3H-thymidine and 3H2O by several of the cellular parameters. Here we shown that at the equal conditions of the incubation of the cells in medium with 3H2O induced the accumulation cells in S-phase without decreasing of the mitotic activity and without increasing of the chromosome aberrations level. Unlike from 3H2O the incubation of the cells with 3H-thymidine induced the accumulation cells in G2-phase with decrease of the mitotic activity and with increase of the chromosome aberrations level. Concurrent treatment cells with 3H-thymidine and thymidine abrogate these cellular effects of the 3H-thymidine. Inhibitor ATM-kinase caffeine abrogate as G2-block as S-phase block. These results suggest that the low-dose beta-radiation activates S-phase and G2-phase checkpoints requiring ATM-mediated signal transduction pathway. The factors, which impact on the efficiency of the internal and of the external sources of the irradiation, depend on theirs disposition in relation to radiosensitive target--DNA was discussed.     

Polyploidization of rat hepatocytes due to cell fusion caused by radiations of different LET

The method of flow cytometry was used to study polyploidization of hepatocytes following X-, gamma-, and neutron-irradiation. Ionizing radiation was shown to induce cell polyploidization by two different ways: (1) cells and nuclei fusion, and (2) restriction of mitosis after DNA replication. RBE of 14 MeV neutrons with respect to fusion was about 5.10(3). With neutron irradiation, the sensitivity of cells by fusion was not lower than that by chromosome mutations.     

Characteristics of the spontaneously transformed human endothelial cell line ECV304. II. Functional responses of the ECV304 cells

Functional responses of the spontaneously transformed human endothelial cell line ECV304 were studied in order to asses its applicability as an endothelial cell model for studying angiogenesis and signal transduction. The dependence of proliferation activity of this line on the presence of growth factor was shown. The absent serum in culture medium resulted in blocking of cells in G1-phase of a cell cycle which is not typical for tumor cell lines. Low doses of beta particles emitted during [3H]thymidine decay resulted in blocking the proliferation of these cells in G2M-phase in a dose-dependent manner. Incubation of the cells with another source of beta particles, 3H2O, under condition of equal specific activities of tritium resulted in preferable accumulation of the cells in S-phase. The different efficiency of beta particles of tritium as a part of 3H2O molecule or thymidine demonstrates that various mechanisms are responsible for various check points. The check point of G1/S is absent and that complies with the presence of deletion of chromosome 9 in locus p21. The level of NO produced by constitutive form of NO-synthase in ECV304 cells was relatively low and not modified by inducible NO-synthase inhibitors. The data obtained suggest that ECV304 line cells retained the properties of the initial spontaneously transformed cell line obtained from human umbilical vein (HUVEC) as well as they can be used as a model system for further studies of the properties of vascular endothelial.     

Internal and external sources of the radiation induce the blocking of the proliferation of the human endothelial cells in culture. G2-block is induced by beta-particle 3H-thymidine and gamma-rays 137Cs

We found that low doses (0.12-0.46Gy) of (methyl-) 3H-thymidine incorporated into human endothelial cells induce the accumulation cells in G2-phase of the cell cycle. Temperate doses of (1-6 Gy) gamma-rays 137Cs were less effective in the G2-block estimated by flow cytometry analysis of DNA content. Furthermore, the induced the high level of the chromosome aberrations (bridges and fragments in anaphases). 1Gy of gamma-ray 137Cs and 0.005 Gy of beta-rays induced the same per cent of the aberrant anaphases. Apparently, that the damages of the cellular hereditary structures are responsible for the blocking of the cellular proliferation in G2-phase. We suggest, that the disposition 3H-thymidine into radiosensitive target (DNA) defines the high cytotoxic of the beta-rays.