Synthetic activity of rat blood lymphocytes under acute and continuous gamma-irradiation – fluorescent microspectral study

The effects of different doses of acute and continuous gamma-irradiation on the synthetic activity of rat blood lymphocytes stained with acridine orange were studied by fluorescent microspectrometry. Male rats were exposed to acute gamma-irradiation with doses of 7.5, 4 and 3 Gy, or to continuous irradiation with dose rates of 14.4, 2.1, 1.1 and 0.43 cGy/day, respectively. The changes of the synthetic activity of blood lymphocytes occurred in three main stages after acute gamma-irradiation and in four stages under continuous irradiation. The stages reflect the processes of depression and activation of the immune system under irradiation. Essential differences between the acute and continuous effects were observed in the first stage. After acute gamma-irradiation, the synthetic activity decreased sharply, indicating the predominant contribution of the damaging effect of irradiation, whereas under continuous irradiation, as a result of the stimulatory effect of low-dose irradiation, the synthetic activity increased during the first stage. Received: 11 May 1998 / Accepted in revised form: 10 January 1999     

Effect of myelopeptides on the postradiation recovery of the thymus

The influence of myelopeptides on the postirradiation recovery of thymus was studied by estimating the thymus cellularity, proliferation of thymocytes in vivo, and composition of thymocyte subpopulations characterized by the expression of Thy-1,2 and Sc-1 antigens and receptors for peanut agglutinin. A single intraperitoneal administration of myelopeptide (the optimal dose of 10(-5) mg/mouse) 24 h following 6.5 Gy irradiation gives rise to proliferative and differentiation processes favoring the recovery of thymus.     

Effect of low doses of low-intensity irradiation on the incidence and progress of spontaneous leukosis in AKR mice

Development of spontaneous leukosis in AKR mice is accelerated by irradiation with low doses (1.2-2.4 cGy, dose-rate 0.6 cGy/day): the leukoses incidence rate increases, deaths of the animals from leukosis occurs earlier, shortening the average and maximum life-spans of the animals. The dynamics of changes in the mass of organs of the immune systems (thymus and spleen) shown extrema. The moment of reaching the extremum correlates with the maximum rate of animals' deaths.     

Vascular and stromal changes in irradiated and recovering rat thymus.

To analyze the mechanisms responsible for thymocyte proliferation, maturation and migration in the thymus, the rat thymus just after, and recovering from irradiation was studied morphologically. The vascular structures of the rat thymus after a radiation dose of 6 Gy were found to be destroyed on day 3, but had recovered to almost normal by day 7, suggesting that the abrupt recovery of thymus structure after irradiation was due primarily to this change in vascular structure. Furthermore, the epithelial tissues in the thymic cortex appeared to contribute to this abrupt proliferation, and possibly to the abrupt maturation of thymocytes, while medullary epithelial tissues remained sparse and appeared inactive for a relatively long period. These findings are considered important for understanding the interrelationship between thymic epithelial cells and thymocytes with respect to thymocyte proliferation, maturation and migration.     

Effect of low doses of ionizing irradiation on viability of cortical thymocytes

The cortical thymocytes of rats in whole organism, isolated lobes of thymus and cells suspension were exposed to ionizing radiation in a wide range of doses (0.1-200 cGy). In contrast to relatively high dose radiation (50-200 cGy), exposure to doses of 10 cGy resulted in cell death without DNA degradation. The level of doses lower than 10 cGy (0.5-5 cGy) induced thymocyte death which is independent of DNA degradation, RNA and protein synthesis. With decrease in radiation dose, the increase of latent period preceding cell death took place.     

Spontaneous leukosis as a model for an investigation of low and very low physical and physico-chemical effects on oncological process

Kinetic investigation of spontaneous leukosis in AKR mice have been carried in connection with a number of indices: changes in the mass of principal organs of the immune systems (thymus, spleen, lymphatic nodes), liver, alterations of haematological data (the sum of leukocytes, the percentage composition of blood cells, the quantity of undifferentiated cells), changes of physico-chemical conditions in cells (NMR-investigation). The dynamics of some of these indices and also life-spans of animals with leukosis after irradiation with doses 1.2-2.4 cGy (dose-rate 0.6 cGy/day) have been investigated. The enhancement of the frequency of leukosis and shortening the average and maximum life-spans of irradiated mice has been found.     

The radioprotective effect of hypothermia on the immune and hematopoietic systems in mammals

The functional activity of the synthetic apparatus (parameter alpha) in blood lymphocytes, bone marrow hemopoietic cells, and thymus cells, as well as the total number of blood and bone marrow cells in rats after y-irradiation at a dose of 8 Gy in the conditions of normothermia and hypothermia (16-18 degrees C) with hypoxia-hypercapnia were investigated after 2 h and on days 1 and 4. The recovery processes in blood in both groups of rats after acute X-irradiation at a dose of 7 Gy for 36 days were analyzed too. Under hypothermia, on days 1-4 after acute gamma-irradiation, a decrease in the synthetic activity in remaining cells and devastation in the hemopoietic system were pronounced to a lesser degree. After X-irradiation, the restoration of synthetic activity in blood lymphocytes was shown to begin earlier and to finish faster in "hypothermic" rats as compared with the animals irradiated in the state of normothermia. The survival of "hypothermic" rats was 100% as compared with 30% in "normothermic" animals. Thus, the data show that hypothermia exerts a radioprotective effect on the cells of the immune and hemopoietic systems, thus enhancing the resistance of the organism to radiation.     

The in vivo effects of a culture medium. II. Influence of culture medium administered prior to irradiation on hemopoietic recovery of gamma-irradiated mice.

The culture medium administered to C57Bl/6 mice 18 h and 8 h before a single irradiation (9 Gy) had a radioprotective effect and clearly influenced postirradiation changes in haemopoiesis. Haemopoiesis recovery appeared to be faster in culture medium-pretreated animals than in those irradiated without such pretreatment. By 12-15 days after irradiation, the thymus cortex appeared to be repaired, on day 21 a multiple increase in extramedullary erythropoiesis, myelopoiesis and megakaryocytopoiesis in the red pulp was found and later, on day 28, the lymphopoiesis in the white pulp of spleen was restored. The rate of haemopoiesis proliferation of predominantly myeloid cells which reached a control level on day 28 following irradiation. Consequently, the regenerative processes in blood-forming organs were accompanied by considerable reticulocytosis and complete recovery of neutrophil and platelet counts in the peripheral blood as seen on day 21. Despite a slower rate complete recovery of the total leukocyte count was reached by day 180 after irradiation.     

Recovery of hematopoiesis in mice following a continuous irradiation with a dose rate of 0.957 Gy/d and a total accumulated dose of 19.14 Gy. I. Bone marrow, spleen and thymus gland

This paper deals with the evaluation of histological changes in the bone marrow, spleen and thymus of mice after continuous irradiation with a dose rate of 0.957 Gy/day and a total accumulated dose of 19.14 Gy. Erythropoiesis in the spleen could be recovered quickly, significantly exceeding the spleen erythropoiesis of the controls on the seventh post-irradiation day. Myelopoiesis in the bone marrow could be recovered until the 21st day and erythropoiesis until the 28th day after the end of irradiation. Lymphopoiesis in the thymus could be recovered on the 28th day approximately and in the spleen roughly on the 60th day after the end of irradiation.     

The effect of dextran sulphate on CFU-S and nucleic acids in blood and haemopoietic tissues in irradiated mice.

The effect of synthetic polyanion dextran sulphate on the development and recovery of radiation-induced haemopoietic damage in mice was investigated. Dextran sulphate (mol. wt. 500,000 D) in the dose of 40 mg.kg-1 of body weight was injected i.p. 3 days before single total body irradiation with a dose of 7.8 Gy gamma-rays. The animals were examined from hour 6 to day 26 after irradiation, i.e. from hour 78 to day 29 after DS-treatment. In irradiated mice DS-pretreatment showed some positive effect on the CFU-S number in bone marrow (less in spleen and blood), bone marrow cellularity, attenuated the radiation-induced changes of erythrocytes (number, MCV) and of RNA concentration in blood. The changes of other parameters (spleen cellularity, liver CFU-S, leukocyte count and DNA concentration in blood) were the same as in unprotected animals. In conclusion, we can say that DS-pretreatment had a beneficial effect on the recovery of radiation-induced damage of erythropoiesis but not on granulopoiesis or lymphopoiesis.     

The effect of a high-intensity radiation exposure on the brain function of monkeys. The postradiation changes in brain bioelectrical activity

In experiments with Macaca fascicularis it has been found that changes in the total bioelectric activity of the brain within the EEG range that occur during the first 60 min following whole-body irradiation with a dose of 45 Gy (6.5 Gy/s) are interrelated with the dynamics of nervous and psychic activity of the exposed animals, exhibit a definite stereotype of their development (disorganization of rhythms: generalized synchronization of biopotentials; and development of synchronous processes), and coincide in time with the main stages of the development of the clinical picture of the acute postirradiation period (noncoordinated stimulation, sopor or coma, and partial recovery).     

Purine metabolizing enzyme activities in radiosensitive tissues of mice after sublethal whole-body irradiation

The activities of adenosine deaminase (ADA) and purine nucleoside phosphorylase (PNP) were determined between days 1-14 in the spleen, thymus and femoral bone marrow of mice subjected to whole-body gama irradiation with a dose of 5.5 Gy. In control animals, the highest activity of ADA (as related to 10(6) cells) was recorded in the thymus (58.9 pmol.s-1), the lowest one in the femur (34.8 pmol.s-1), the PNP activity was the lowest in the thymus (14.5 pmol.s-1) and the highest in the femur (96.0 pmol.s-1). In the spleen, an elevation of ADA activity (up to 379%) was observed during the first postirradiation days; PNP activity was reduced (to 58%) on postirradiation day 3, followed by the return and even elevation on day 14 (265%). In the thymus, a parallel reduction of the activities of both enzymes appeared during the first postirradiation days, with a subsequent increase during the regeneration phase. In the femoral bone marrow, ADA and PNP activities were increased on postirradiation day 1 (275% and 201%, respectively). Reference is made to the possible relationship between the observed characteristic changes in activities and the degree of damage and/or renewal of cell population in the hemopoietic tissues after irradiation.     

A Cellular Automata-Based Mathematical Model for Thymocyte Development

Intrathymic T cell development is an important process necessary for the normal formation of cell-mediated immune responses. Importantly, such a process depends on interactions of developing thymocytes with cellular and extracellular elements of the thymic microenvironment. Additionally, it includes a series of oriented and tunely regulated migration events, ultimately allowing mature cells to cross endothelial barriers and leave the organ. Herein we built a cellular automata-based mathematical model for thymocyte migration and development. The rules comprised in this model take into account the main stages of thymocyte development, two-dimensional sections of the normal thymic microenvironmental network, as well as the chemokines involved in intrathymic cell migration. Parameters of our computer simulations with further adjusted to results derived from previous experimental data using sub-lethally irradiated mice, in which thymus recovery can be evaluated. The model fitted with the increasing numbers of each CD4/CD8-defined thymocyte subset. It was further validated since it fitted with the times of permanence experimentally ascertained in each CD4/CD8-defined differentiation stage. Importantly, correlations using the whole mean volume of young normal adult mice revealed that the numbers of cells generated in silico with the mathematical model fall within the range of total thymocyte numbers seen in these animals. Furthermore, simulations made with a human thymic epithelial network using the same mathematical model generated similar profiles for temporal evolution of thymocyte developmental stages. Lastly, we provided in silico evidence that the thymus architecture is important in the thymocyte development, since changes in the epithelial network result in different theoretical profiles for T cell development/migration. This model likely can be used to predict thymocyte evolution following therapeutic strategies designed for recovery of the thymus in diseases coursing with thymus involution, such as some primary immunodeficiencies, acute infections, and malnutrition.     

Response of a brachytherapy model using 125I in a murine tumor system

The effects of low-dose-rate irradiation (brachytherapy) were investigated in vivo using a murine mammary adenocarcinoma (MTG-B) growing in the flank of C3H mice. For local tumor irradiations, a noninvasive cap was devised to cover the tumor and house three 125I seeds (average apparent activity 5.2 mCi each) located at 120 degree intervals around the circumference of the hemispherical cap (13 mm i.d.). Mice were secured during treatment in a tube allowing limited mobility while restricting access to the seeds. Tumors were exposed to a series of dose rates ranging from 14-40 cGy/h, and the total dose over the treatment interval (48 or 72 h) ranged from 830 to 2378 cGy. A total of nine experiments were conducted using the caps over a 10-week interval. In each experiment three groups (irradiated tumors, sham controls, and untreated controls) were analyzed, each containing 8-15 mice (N = 34, untreated control; N = 46, sham control; N = 91, brachytherapy irradiation). The brachytherapy results are compared to the effects of external beam irradiation in the same tumor system. A linear relationship was observed between the total radiation dose and doubling volume growth delay (GDDV) or treatment volume growth delay (GDTV) for the brachytherapy and external beam irradiation. The slopes of the dose-response curves are steeper for the acute dose (517 cGy/min) external beam irradiation (0.0072 day/cGy, GDDV; 0.00695 day/cGy, GDTV) than for the brachytherapy (0.0050 day/cGy, GDDV; 0.0057 day/cGy, GDTV) using both GDTV and GDDV end points. Comparison of the tumor volume regrowth slopes indicates that the tumor bed effect is larger for external beam irradiation than for brachytherapy, suggesting that the tumor bed effect may be dose-rate dependent.     

Immune effects of low-dose radiation: short-term induction of thymocyte apoptosis and long-term augmentation of T-cell-dependent immune responses

We and others have shown that low-dose X or gamma irradiation of mice leads to an increase in their survival after a subsequent lethal high-dose irradiation. The greatest increase in radioresistance appears at a fixed window of dose and time, e.g. 8 weeks after 5-10 cGy or 2 weeks after 50 cGy preirradiation. We show that low-dose irradiation induces thymocyte apoptosis with a maximal level at 6 h postirradiation that returns to background levels after 24 h. At the same time, we observed no morphological alteration of splenocytes and no early modification of the intensity of T-cell-dependent immune responses as measured by plaque-forming cell (PFC) counts. Nevertheless, we found that PFCs were increased 2 weeks after 50 cGy irradiation, which is the same time at which mice expressed the optimal increase in survival after a second lethal irradiation. We also examined thymocyte apoptosis and spleen PFCs in mice subjected to other stress-inducing pretreatments. Our results emphasize the existence of a lag time between the time of low-dose irradiation in vivo and the appearance of radioresistance. A mechanism that interconnects an environmental stimulus with the response of the animal is proposed based on the evidence presented here and reported in the literature.     

Modification of the regulatory effects of thymocytes on hematopoiesis in irradiated mice as affected by heterologous immunoglobulin G and low-dose ionizing radiation

The administration of heterologous immunoglobulin G (IgG) and/or exposure of mouse thymocyte donors to 1 and 2 Gy radiation were shown to change the regulatory effects of thymus lymphocytes on the recovery of haemopoiesis in syngeneic recipients irradiated with a median lethal dose of 6 Gy. Thymocytes of exposed (2 Gy) donors produced a stimulatory effect on the restoration of the myelokaryocytes number and increased the number of endogenous splenic colonies and bone marrow CFUs in animals exposed to a median lethal dose, whereas the administration of IgG to thymocyte donors given 2 Gy eliminated the stimulatory effect of thymocytes on the number of myelokaryocytes, and the amount of CFUs in irradiated recipients decreased.     

The immunomodulating action of microwaves in the induction of an immune response to Vi antigen

In this work the possibility of using microwaves for immunomodulation in the immunization of animals with thymus-independent antigen was studied. The projection zones of the thymus and adrenal glands of the test animals were subjected to the action of decimeter, or ultrahigh frequency (UHF), waves, while the corresponding zones of the control animals were subjected to imitation UHF irradiation. Vi-antigen was shown to be a thymus-independent antigen for rabbits (according to the results of the evaluation of the functional state of thymocytes, as manifested by the adsorption of acridine orange by the chromatin of thymocyte nuclei and by the content of RNA and DNA in the thymus). The action of UHF waves on the projection zone of the thymus was accompanied by a decrease in the glucocorticoid activity of the adrenal cortex, observed simultaneously with a pronounced immunostimulating effect. The UHF irradiation of the zone of the adrenal glands was accompanied by immunosuppression in combination with enhanced glucocorticoid activity of the adrenal cortex.     

Effect of monosodium glutamate on oxidative stress and apoptosis in rat thymus

It has been demonstrated that administration of high concentrations of monosodium glutamate (MSG), induce oxidative stress in different organs, but not in thymus. In the present study we examined the role of oxidative stress in MSG-induced thymocyte apoptosis. MSG was administrated intraperitoneally (4 mg/g of body weight) for six consecutive days. Animals were sacrificed at 1st, 7th, and 15th day after last MSG dose. MSG administration to animals significantly increased apoptotic rate of thymocytes (P < 0.01), together with significant increase of malondialdehyde (MDA) level (P < 0.001) and xanthine oxidase (XO) activity (P < 0.01), in time dependent manner. Catalase activity, during examination period, was significantly decreased (0 < 0.01). Obtained results showed that MSG treatment induced oxidative stress in thymus, which may have an important role in thymocyte apoptosis induced by MSG.     

Radiation damage repair capacity of a human germ-cell tumour cell line: inhibition by 3-aminobenzamide

The capacity of a human germ-cell tumour line to repair radiation damage has been investigated by means of a clonogenic assay. Dose-rate dependence studies, split-dose experiments and experiments designed to measure repair of potentially lethal damage have been performed. The cells showed some ability to repair radiation-induced damage in all three types of experiment. An attempt has been made to understand the possible cellular mechanisms of these repair processes by the use of 3-aminobenzamide (3-AB), an agent thought to act by inhibition of ADP-ribosylation. 3-AB added 2 h prior to and removed 18 h after irradiation at a non-toxic dose to unirradiated cells caused a small but consistent increase in cell kill with acute (150 cGy min-1) irradiation, largely involving a reduction in the shoulder region of the survival curve, but had a greater effect in increasing cell kill at a dose rate of 7.6 cGy min-1 and an even greater effect at a dose rate of 1.6 cGy min-1. When 3-Ab was present 2 h prior to the first dose and between two equal doses in a split-dose experiment, inhibition of split-dose recovery was observed. In addition, some inhibition of potentially lethal damage recovery was observed with 3-AB. A possible role for poly(ADP-ribosylation) is thus implicated in the repair of radiation-induced damage of this human tumour cell line during continuous low dose rate or fractionated radiation schedules, although other effects of 3-AB on respiratory metabolism and/or purine synthesis cannot be eliminated as the cause of the observed inhibitory effects.     

Ultrastructure of cells of rat lymphatic organs during continuous irradiation

Changes in the ultrastructures of lymphatic organs of rats observed from the 2nd to 22nd day following continuous irradiation with gamma rays at a daily dose of 115 mGy (exposition: 12 R/day) are described. The maximum of destructive changes in lymphocytes was observed on the 11th to the 14th day of irradiation. A gradual balance between dystrophic and regenerative processes was achieved on the 18th day. In this connection to correlation could be determined between the ultrastructural changes described and the fluctuations of lymphocyte numbers in the lymphatic organs and peripheral blood during continuous irradiation.