Characteristics of chromatin breakdown in the rat thymus after exposure to fast neutrons and gamma rays

A comparative study was made of the radiobiological aftereffects of the action of fast neutrons and gamma-rays on lymphoid tissues of rat thymus with a reference to a biochemical criterion of the interphase death of lymphocytes, i.e. the formation of polydeoxynucleotides (PDN). It was shown that the increase in the chromatin degradation was a function of dose of neutron- and gamma-radiation (up to 4 Gy). The dynamics of the PDN formation was similar with both types of radiation, but 4-6 h after neutron irradiation chromatin degradation was higher more pronounced. The RBE of neutrons varied from 3 to 2 with a radiation dose varying from 0.25 to 4 Gy.     

Conformational properties of DNA after exposure to gamma rays and neutrons

DNA aqueous solutions were irradiated with 0-40 Gy of 60Co gamma rays and 0-1.5 Gy of (Pu-Be) neutrons. Thermal transition spectrophotometry (TTS) was used to trace the changes in the DNA conformation at the above doses. Previous results using the perturbed angular correlation (PAC) method were used to complement to the current analysis. The TTS and PAC methods are two different approaches to the study of the effects of radiation on DNA. Both showed that neutrons are more effective than gamma rays in inducing DNA damage. The TTS method showed that neutrons are 11 +/- 5 times more efficient than gamma rays, while the PAC method had shown this value to be 34 +/- 4. From the current study we deduced that the radiation damage to DNA is not a spontaneous effect but rather is an ensemble of damaging events that occur asynchronously. Any single method selected for the study of such damages can concentrate on only a part of the damage, leading to over- or underestimation of the relative effectiveness of the neutrons.     

The proteinase activity in the cell nuclei of rats following exposure to gamma radiation and methylnitrosourea

Activity of nuclear proteinases in blood and liver cells of rats exposed to whole-body gamma-irradiation (10 Gy) has been comparatively studied by the capacity of splitting the casein substrate. Proteinase activity in nuclei of irradiated rat leukocytes was shown to increase by 2.5 times and to gradually decrease after 48 h reaching 150-160% as compared to the control. Two hours following a single injection of methyl nitrosourea the alteration in the activity of proteinases in nuclei of rat hepatocytes and leukocytes was different from the alteration of this index after gamma-irradiation.     

Evidence for similarities between radiation damage expressed by beta-araA and damage involved in the interaction effect observed after exposure of V79 cells to mixed neutrons and gamma radiation

Plateau-phase V79 cells were exposed sequentially to fast neutrons and gamma rays. A dose-dependent reduction in the shoulder width of the gamma-ray survival curve was observed after preexposure of cells to neutrons. A similar effect was demonstrated on the neutron survival curve when cells were preirradiated with gamma rays. Treatment of cells with 150 microM beta-araA after either gamma or neutron irradiation reduced primarily the shoulder of the survival curve. When beta-araA was given to the cells after exposure to mixed radiation modalities, survival curves similar to those observed after exposure to a single radiation modality and treatment with beta-araA were obtained. The kinetics of loss of the interaction observed after exposure of cells to gamma rays following neutron irradiation was similar to the kinetics of loss of sensitivity to beta-araA (T1/2 = 1 h) measured by delaying drug administration after exposure to gamma rays. The results suggest that the PLD expressed by beta-araA is at least partly involved in the interactive effect observed after combined exposure of plateau-phase V79 cells to neutrons and gamma rays.     

Life shortening in mice exposed to fission neutrons and gamma rays. VIII. Exposures to continuous gamma radiation

Data are presented on the mean aftersurvival of male B6CF1 mice exposed for 22 h per day, 5 days per week, to 60Co gamma radiation at dose rates of 1.36 to 12.64 x 10(-3) cGy/min for 23 weeks or 1.36 to 6.32 x 10(-3) cGy/min for 59 weeks. For deaths from all causes, linear dose-response curves were obtained with slopes (days of life lost/cGy) of 0.158 +/- 0.016 and 0.077 +/- 0.002 for 23- and 59-week exposures, respectively. These values were not significantly altered when the analysis was restricted to those mice dying with tumors (92% of the total) or to those presumably dying from tumors (82% of the total). Analysis of mortality rates showed that about 90% of the radiation-specific excess mortality was tumor related. The 59-week exposure series induced only a small increase in the number of days of life lost/cGy/weekly fraction over that induced by 23 weeks of irradiation, 4.53 +/- 0.15 compared to 3.64 +/- 0.36 days lost/cGy/weekly fraction. This lower than expected value for 59 weeks of exposure may signal the approach to the final linear, additive, injury term postulated from earlier studies at this laboratory with low-dose-rate, daily, duration-of-life 60Co gamma irradiation.     

Chromosome aberration peristence in swine leukocytes following exposure to fission neutrons

Chromosome aberration rates in swine lymphocytes decreased rapidly within the first 24 h postirradiation. This initial loss coincided with a decrease in lymphocyte number and continued until lymphocyte numbers began to recover at 7 days after irradiation. Subsequent losses were less dramatic, and numbers of acentric fragments reached preirradiation levels by 56 days postexposure; rings and dicentrics persisted throughout the 84-day study. Mathematical models descrine the predicted aberration yield as a function of time after irradiation. The disappearance rate of aberrant lymphocytes after irradiation suggests that anerration persistence kinetics should be considered when using lymphocyte aberrations as biologic dosimeters.     

RBE for carcinogenesis following exposure to high LET radiation

Stochastic radiation effects following exposure to heavy ions and other high linear energy transfer (LET) radiation in space are a matter of concern when the long-term consequences of space flights are considered. This paper is an overview of the relevant literature, emphasizing uncertainties entailed from estimates of relative biological effectiveness (RBE) for different experiment end-points, making the choice of a single weighting factor for the prediction of cancer risk in man extremely difficult. Life-span-shortening studies in mice exposed to heavy ions and ongoing large-scale experiments in monkeys exposed to protons suggest that RBEs for all cancers are lower than 5. This does not exclude a much higher RBE for rare tumors such as brain tumors in monkeys or promoted Harderian gland tumours in mice at LET >80 keV/µm. Skin cancer studies in rats exposed to neon or argon resulted in similar RBE. Exposure to fission neutrons led to high RBE in all species, not excluding values much higher than 20 for specific cancers such as lung tumors in mice and all cancers in rats. The estimate of maximal RBE is, however, extremely dependent on the hypothesis made on the shape of the dose-response curves in the lower range of doses. These results suggest that neutrons may be the most hazardous component of high-LET radiation. There is only limited evidence from cancer experiments that LET >150 keV/µm results in highly decreased efficiency, but this has been found for bone cancer induction following exposure to fission fragments.Invited paper presented at the International Symposium on Heavy Ion Research: Space, Radiation Protection and Therapy, Sophia-Antipolis, France, 21–24 March 1994     

Protection against genotoxic damages following whole body gamma radiation exposure in mice by lipoic acid

Alpha-lipoic acid (LA) protected plasmid pBR 322 DNA, under in vitro conditions from gamma radiation induced strand breaks as evidenced by the prevention of the loss of supercoiled covalently closed circular form upon irradiation. It also protected the membrane lipids of liver homogenates from the oxidative damages. Whole body exposure of mice to gamma-radiation resulted in damage to cellular DNA in various tissues and administration of LA prior to the radiation exposure prevented the radiation induced DNA damage as assessed by alkaline comet assay. Administration of LA to mice prior to the radiation exposure also prevented induction of chromosomal damages in bone marrow cells and formation of micronuclei in blood reticulocytes. Thus taken together, LA a normal cellular constituent could be used as a radioprotector against whole body radiation exposure scenarios.     

Mechanism of thymocyte death in exposure to ultrahigh doses of gamma radiation

A comparative study was made of the morphological and biochemical indices of rat thymus cells after gamma-irradiation with doses of 4-10 Gy (median), 20 Gy (high), and 200-400 Gy (superhigh). It was shown that 4 h after irradiation with superhigh doses the yield of polydeoxynucleotides (PDN) was twice as low as that observed after doses of 4-10 Gy. 24 h after irradiation the amount of the extracted PDN in thymocytes exposed to superhigh doses was markedly larger than that after 4 hours. After all doses applied chromatin degradation occurred at the internucleosome sites in a strict order, the activity of acid and alkaline nucleases being unchanged. A large number of cells have normal nuclear structure 4 h after irradiation (200-400 Gy), as was demonstrated by the electron microscopy data, while in 24 h no intact cells were virtually found in the thymus which correlated with the changes in the PDN yield. The mechanisms of the lymphoid cell death under the effect of different radiation doses are discussed.     

Alterations in the rat forebrain apoptosis following exposure to ionizing radiation

Ionizing radiation commonly used in the radiotherapy of brain tumours can cause adverse side effects to surrounding normal brain tissue. The most significant response of adult brain to radiation damage is induction of apoptosis. The adult mammalian subventricular zone (SVZ) of the brain lateral ventricles (LV) and their subsequent lateral ventricular extension, the rostral migratory stream (RMS), is one of the few areas, which retains the ability to generate new neurons and glial cells throughout life. Taking into account the fact, that ionizing radiation is one of the strongest exogenous factors affecting cell proliferation, the aim of the present study was to investigate the occurrence of radiation-induced apoptosis in this neurogenic region. Adult male Wistar rats were investigated 1, 5 or 10 days after single whole-body gamma irradiation with the dose of 3 Gy. Apoptotic cell death was determined by in situ labelling of DNA nick ends (TUNEL) and fluorescence microscopy evaluation of TUNEL-positive cells. Considerable increase of apoptotic TUNEL-positive cells was observed 24 hrs after irradiation in caudal parts of RMS; i.e. in the vertical arm and elbow of RMS. Initial increase was followed by strong reduction of apoptosis in the RMS and by secondary over-accumulation of apoptotic cells in the animals that survived ten days after exposure. Results showed, that the proliferating population of cells, arisen in SVZ are highly sensitive to radiation-induced apoptosis. This observation should have implications for clinical radiotherapy to avoid complications in therapeutic brain irradiation.     

Testicular function of rats following exposure to microwave radiation

Male Sprague-Dawley rats were exposed for 6 h per day for nine days to pulse-modulated microwave radiation (1.3 GHz, at 1-microseconds pulse width, 600 pulses per second). Exposures were carried out in cylindrical waveguide sections at a mean dose rate of 6.3 mW/g; sham controls were treated similarly and received no irradiation. At time periods corresponding to 0.5, 1.0, 2.0, and 4.0 cycles of the seminiferous epithelium, groups of four sham-irradiated and four irradiated rats were killed and the testes removed for analysis. Net mass of the testes, epididymides, and seminal vesicles; daily sperm production (DSP) per testis and per gram of testis; sperm morphology; and the number of epididymal sperm were determined. There were no statistically significant differences between the sham-irradiated and irradiated groups with respect to any measured variable. In a group of seven surrogate animals of similar body mass, the dose rate of 6.3 mW/g caused a net change in body temperature (via rectal probe) of 1.5 degrees C.     

Alkaline phosphatase and transaminase activity in the liver and blood serum of rats in the late periods following combined exposure to external gamma radiation and alpha radiation from plutonium-239

A study was made of activity of alkaline phosphatase and alanine- and aspartate aminotransferase in rat liver and blood serum at remote times after external gamma-irradiation combined with internal exposure to 239Pu nitrate delivered in two chronically effective doses. The radionuclide was shown to be mainly responsible for the changes observed in activity of the enzymes under study. The degree to which the changes were manifest depended upon dose of plutonium administered.     

Cellular proto-oncogene expression following exposure of mice to gamma rays.

Many studies have shown the importance of altered cellular proto-oncogene expression in contributing to changes in cell survival, cell transformation, and cell cycle progression. In these experiments we examined the effects of total-body exposure of BCF1 mice to gamma rays (3 Gy) in modulating expression of cellular oncogenes in both gut and liver tissues. We selected specific cellular oncogenes (c-fos, c-myc, c-src, and c-H-ras), based on their normal expression in liver and gut tissues from untreated mice. As early as 5 min following whole-body exposure of BCF1 mice to gamma rays we detected induction of mRNA specific for c-src and c-H-ras in both liver and gut tissues. Accumulation of c-fos-RNA was slightly decreased in gut but was unaffected in liver tissue from irradiated mice relative to untreated controls. Accumulation of c-myc mRNA was unaffected in all tissues examined. These experiments document that modulation of cellular proto-oncogene expression can occur as an early event in tissues following irradiation and suggest that this modulation may play a role in radiation-induced cellular changes.     

Genetic effect of chronic gamma radiation exposure in male mice

The frequency of reciprocal translocations (RT) in mouse spermatogonia induced by gamma-rays at doses of 1.5 to 4.5 Gy and dose rates of 2.7 X 10(-6), 5.8 X 10(-6), 9.4 X 10(-5) and 4.5 Gy/min was studied. A linear increase was observed in the RT frequency with increasing the dose, at all dose rates. At 9.4 X 10(-5) Gy/min the RT frequency was, on average, 10 times lower, as compared to that for a single acute dose rate of 4.5 Gy/min. Further reduction of the dose rate did not result in a decrease of the RT yield, and at the lowest dose rate of 2.7 X 10(-6) Gy/min (the dose being 3.0 Gy) the RT frequency was higher than using the same dose at dose rates of 5.8 X 10(-6) and 9.4 X 10(-5) Gy/min. Possible reasons for an increase in the RT frequency at low dose rates are considered. A study of the frequency of abnormal sperm heads (ASH) has shown that at the dose rate of 9.4 X 10(-5) Gy/min it is independent of an accumulated dose and is equal to the value obtained when exposing to an acute dose of 3.0 Gy. At dose rates of 2.7 X 10(-6) and 5.8 X 10(-6) Gy/min ASH frequencies were only slightly increased at all doses, as compared to the control level.