Cytogenetic effects in children exposed to low doses of ionizing radiation

The obtained data indicate that frequencies of different types of cytogenetic anomalies in investigated children groups living in radionuclide contaminated territories and children irradiated in utero have complicated patterns. The frequency of chromosomal anomalies in the investigated groups of children exceeds the average population level. At the same time, no statistically significant differences in frequencies of various types aberrations between groups of children were revealed.     

Genetic and somatic effects of ionizing radiation in humans and animals (comparative aspect)

Genetic effects of ionizing radiation in the progeny of exposed parents could be conventionally subdivided on three main types. 1. Severe developmental disorders (fetus death, stillbirth, early postnatal mortality, malformation, hereditary disease, sterility). These effects are known to be caused by so called "gross" mutations (genomic, chromosomal, those of essential genes) with dominant harmful effects. Although found in rodents, insects, fishes they have not been found in humans. The proposal is made that the higher reproductive potency of a species the higher its tolerance for defective organisms. Due to strong selection against severe defects at the earliest stage of pregnancy, this genetic effect of radiation is likely to be difficult to detect in people. 2. Increased cancer risk manifested as elevated incidence of spontaneous tumors and increased sensitivity to carcinogenic agents. 3. Decreased fitness (non-carcinogenic negative health effects). These two last types of radiation genetic effects are presumably due to instability and functional inferiority of cell genome in the progeny of irradiated parents. The genetic background of these effects is suggested to be the load of induced minor mutations in regulatory genes (mini-, microsatelite loci) or/and epigenomic rearrangements of DNA in parental germ cells transmitted to progeny. These radiation genetic effects are much more obvious in animals as compared to humans. Apparently, they are difficult to find in humans because of their essential dependence on promotive (life style) factors, which are impossible to control in the offspring of irradiated people. A comparison of somatic (in irradiated organisms) and genetic (in the progeny of irradiated parents) effects of radiation provide evidence on the phenomenological as well as pathogenic similarity.     

A systematic review of epidemiological associations between low and moderate doses of ionizing radiation and late cardiovascular effects, and their possible mechanisms

Little, M. P., Tawn, E. J., Tzoulaki, I., Wakeford, R., Hildebrandt, G., Paris, F., Tapio, S. and Elliott, P. A Systematic Review of Epidemiological Associations Between Low and Moderate Doses of Ionizing Radiation and Late Cardiovascular Effects, and Their Possible Mechanisms. Radiat. Res. 169, 99-109 (2008). The link between high doses of ionizing radiation and damage to the heart and coronary arteries is established. In this paper, we systematically review the epidemiological evidence for associations between low and moderate doses (<5 Gy) of ionizing radiation and late-occurring cardiovascular disease. Risks per unit dose in epidemiological studies vary over at least two orders of magnitude, possibly a result of confounding factors. An examination of possible biological mechanisms indicates that the most likely causative effect of radiation exposure is damage to endothelial cells and subsequent induction of an inflammatory response, although it seems unlikely that this would extend to low-dose and low-dose-rate exposure. However, a role for somatic mutation has been proposed that would indicate a stochastic effect. In the absence of a convincing mechanistic explanation of epidemiological evidence that is less than persuasive at present, a cause-and-effect interpretation of the reported statistical associations cannot be reliably inferred, although neither can it be reliably excluded. Further epidemiological and biological evidence will allow a firmer conclusion to be drawn.     

Early effects of low doses of ionizing radiation on the fetal cerebral cortex in rats

Pregnant rats were exposed to gamma radiation from a 137Cs irradiator on gestational Day 15. Fetuses that received 0.25, 0.5, 0.75, or 1.0 Gy were examined 24 h after irradiation for changes in the cells of the cerebral mantle of the developing brain. The extent of changes following 0.5 Gy was studied at 3, 6, 12, or 24 h after exposure. Cortical thickness of the cerebral mantle was not significantly altered. The number of pyknotic cells, number of macrophages, nuclear area, and number of mitotic cells were altered in a dose-related way. The number of pyknotic cells was significantly increased at all doses. A positive correlation between the number of pyknotic cells and the number of macrophages developed with time. At 3 h after irradiation about 60% of pyknotic cells were found in the subventricular zone and about 25% in the intermediate zone and cortical plate. The number of such cells in the upper layers of the cortex steadily increased up to 24 h, at which time about 70% of pyknotic cells were in these two layers. The relationship of the movement of pyknotic cells to migration of postmitotic neuroblasts is discussed.     

Radiation effects in Caenorhabditis elegans, mutagenesis by high and low LET ionizing radiation

The nematode C. elegans was used to measure the effectiveness of high-energy ionized particles in the induction of 3 types of genetic lesions. Recessive lethal mutations in a 40-map unit autosomal region, sterility, and X-chromosome nondisjunction or damage were investigated. Induction rates were measured as a function of linear energy transfer, LET infinity, for 9 ions of atomic number 1-57 accelerated at the BEVALAC accelerator. Linear kinetics were observed for all 3 types of lesions within the dose/fluence ranges tested and varied strongly as a function of particle LET infinity. Relative Biological Effectiveness (RBE) values of up to 4.2 were measured and action cross sections were calculated and compared to mutagenic responses in other systems.     

The effects of low doses of low-intensity ionizing radiation on DNA structure and function

Chronic effects of low doses of low-intensity ionizing radiation (IR) on biological objects have gained great social significance. This has given a considerable impetus to research into the biological effects and mechanisms of such exposures, both in Russia and abroad. In this paper, an overview of the physicochemical and molecular basis of IR influence at low doses is provided. Means of cell protection from radiation damage are studied and an analysis of the typical features and differences in the radiation effects at low and high doses is carried out. We considered DNA radiation damage, both in cell cultures and in vivo, as well as the processes and results of their repair. Particular attention is paid to changes in the basic paradigms of biological radiation effects at low doses.     

Health risks of low dose ionizing radiation in humans: a review

Radiobiologists have been struggling to estimate the health risks from low doses of radiation in humans for decades. Health risks involve not only neoplastic diseases but also somatic mutations that may contribute to other illnesses (including birth defects and ocular maladies) and heritable mutations that may increase the risk of diseases in future generations. Low dose radiation-induced cancer in humans depends on several variables, and most of these variables are not possible to correct for in any epidemiologic study. Some of the confounding factors include (i) interaction of radiation with other physical (UV light), chemical, and biological mutagens and carcinogens in a synergistic manner; (ii) variation in repair mechanisms that depend on dose; (iii) variation in sensitivity of bystander cells to subsequent radiation exposure that depends on whether they have been pre- or postirradiated; and (iv) variation in adaptive response that depends on radiation doses and protective substances (antioxidants). In our opinion, both the linear no-threshold-response and the threshold-response models might not be suitable in predicting cancer risk at low radiation doses in a quantitative sense. Low doses of ionizing radiation should not be considered insignificant for risks of somatic and heritable mutations and neoplastic and nonneoplastic diseases in humans.     

Low doses of ionizing radiation and circulatory diseases: a systematic review of the published epidemiological evidence

Recent analyses of mortality among atomic bomb survivors have suggested a linear dose-response relationship between ionizing radiation and diseases of the circulatory system for exposures in the range 0-4 Sv. If confirmed, this has substantial implications. We have therefore reviewed the published literature to see if other epidemiological data support this finding. Other studies allowing a comparison of the rates of circulatory disease in individuals drawn from the same population but exposed to ionizing radiation at different levels within the range 0-5 Gy or 0-5 Sv were identified through systematic literature searches. Twenty-six studies were identified. In some, disease rates among those exposed at different levels may have differed for reasons unrelated to radiation exposure, while many had low power to detect effects of the relevant magnitude. Among the remainder, one study found appreciable evidence that exposure to low-dose radiation was associated with circulatory diseases, but five others, all with appreciable power, did not. We conclude that the other epidemiological data do not at present provide clear evidence of a risk of circulatory diseases at doses of ionizing radiation in the range 0-4 Sv, as suggested by the atomic bomb survivors. Further evidence is needed to characterize the possible risk.     

Using DNA microarray data to understand the ionizing radiation resistance of Deinococcus radiodurans

In a recent paper, Liu et al. documented the changes in gene expression as stationary phase Deinococcus radiodurans cultures recover from acute exposure to gamma radiation. Given that the biochemical details of the response of D. radiodurans to ionizing radiation are poorly understood, this work represents an important first step towards achieving an understanding of the ionizing radiation resistance in this species.     

Non-monotonous dose-response relationship in the region of low doses of ionizing radiation

The statement about nonmonotony of dose-effect curves as a result of nonmonotony of the time-effect relationship including the field of low doses is discussed. The living cells possess a fundamental property to response to action of different stress agents by oscillatory--nonmonotonous--hanges of metabolism. The systems keeping up homeostasis by direct and feed-back regulation return metabolism to norm. In the fixed temporary point a dose-effect dependence may take the nonmonotonous character e.g. reverse dose-response relationship. The changes of the oscillation parameters suggested the inclusion of the different pathway for homeostasis keeping. Radiation hormesis does not focused on the metabolic and functional nonmonotonous response. Radiation stimulation is considered as consequence of the peculiarity of the homeostasis maintenance pathways in the certain interval of the low doses of ionizing radiation.     

The micronucleus assay as a biological dosimeter in hospital workers exposed to low doses of ionizing radiation

The health risk associated with low levels of ionizing radiation is still a matter of debate. A number of factors, such as non-target effects, adaptive responses and low-dose hypersensitivity, affect the long-term outcome of low-dose exposures. Cytogenetic bio-dosimetry provides a measure of the absorbed dose, taking into account the individual radiation sensitivity. The aim of the present study is to evaluate the value of the micronucleus (MN) test as a bio-dosimeter in hospital workers exposed to low doses of ionizing radiation. Blood samples were obtained from 30 subjects selected among workers exposed to X- and gamma-radiation, and 30 controls matched for sex, age and smoking from the same hospital. Micronucleus frequencies were analyzed by use of the cytokinesis-block method. The MN frequency was compared among the groups considering the confounding factors and the length of employment. No increase in the number of bi-nucleated cells with MN (BNMN), but a significant increase in the number of mono-nucleated cells with micronuclei (MOMN) was observed in exposed subjects compared with the controls. The relationship between MN frequency and accumulated dose (mSv) was evaluated. The length of employment did not affect the extent of MN frequency, but an increase of BNMN and MOMN cells was observed based on the accumulated radiation dose. Our study shows the sensitivity of the MN test in the detection of cytogenetic effects of cumulative exposure levels, suggesting the potential usefulness of this assay in providing a biological index in medical surveillance programs.     

Neoplastic transformation in vitro by low doses of ionizing radiation: role of adaptive response and bystander effects

The shape of the dose-response curve for cancer induction by low doses of ionizing radiation is of critical importance to the assessment of cancer risk at such doses. Epidemiologic analyses are limited by sensitivity to doses typically greater than 50-100 mGy for low LET radiation. Laboratory studies allow for the examination of lower doses using cancer-relevant endpoints. One such endpoint is neoplastic transformation in vitro. It is known that this endpoint is responsive to both adaptive response and bystander effects. The relative balance of these processes is likely to play an important role in determining the shape of the dose-response curve at low doses. A factor that may influence this balance is cell density at time of irradiation. The findings reported in this paper indicate that the transformation suppressive effect of low doses previously seen following irradiation of sub-confluent cultures, and attributed to an adaptive response, is reduced for irradiated confluent cultures. However, even under these conditions designed to optimize the role of bystander effects the data do not fit a linear no-threshold model and are still consistent with the notion of a threshold dose for neoplastic transformation in vitro by low LET radiation.