Abstract
In this paper the results of research at 5–10 and 24 years after the Chernobyl accident are summarized. These results include the investigation of genomic instability, formation of the adaptive response, genome damage, and oxidative status. The studies were performed on cells in culture, mice, children and adults who lived in the contaminated areas, and liquidators of the consequences of the Chernobyl accident. Inhibition of cell proliferative activity, late cell death, and the increase in micronucleus and giant cell frequency were observed after the exposure of cells in culture in the accident zone followed by their culturing in laboratory conditions. In the progeny of the exposed cells, the effect of enhanced radiosensitivity was detected. Thus, it can be assumed that exposure of parental cells in culture in the area of the accident induced genomic instability that resulted in the development of various abnormalities in progeny cells. At the organism level, the Chernobyl zone exposure of mice caused an increase in radiosensitivity; as well, a decrease in the endotheliocyte density in the cerebral cortex and other brain tissues was observed. In the blood lymphocytes of children stimulated by PHA, a more than two times increase in micronucleus cell frequency was detected. A reduced number of individuals with significant adaptive response was found in both the juvenile and adult groups. In all investigated populations, an increased number of individuals with enhanced radiosensitivity were observed in response to low-dose radiation exposure. At 24 years after the accident liquidators were subjected to examinations, which revealed an increased frequency of cells with micronuclei and chromosome-type aberrations in blood lymphocytes, an elevated level of DNA double strand breaks, and a reduced level of reactive oxygen species compared to those of the control group. This means that the genomic instability that was accumulated by the residents of the contaminated regions and liquidators as a result of the accident leads to damage of the genetic apparatus, an increase in radiosensitivity, and hypoxia as late consequences that all are risk factors and increase the probability of the development of tumor and non-tumor diseases. The development of the above-mentioned pathological processes may occur in the distant future.
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Original Russian Text © I.I. Pelevina, G.G. Afanas’ev, A.V. Aleshchenko, M.M. Antoshchina, V.Ya. Gotlib, A.A. Konradov, O.V. Kudryashova, E.Yu. Lizunova, A.N. Osipov, N.I. Ryabchenko, A.M. Serebryanyi, 2011, published in Radiatsionnaya Biologiya. Radioekologiya, 2011, Vol. 51, No. 1, pp. 154–161.
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Pelevina, I.I., Afanas’ev, G.G., Aleshchenko, A.V. et al. The molecular and cellular consequences of the chernobyl accident. BIOPHYSICS 56, 577–583 (2011). https://doi.org/10.1134/S0006350911030237
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DOI: https://doi.org/10.1134/S0006350911030237