Time- and dose-dependent post-irradiation changes of Fe3+-transferrin and Cu2+-ceruloplasmin pools in blood, their influence on ribonucleotide reductase activity in animal tissues and the effects of radioprotectors

The time- and dose-dependent changes of Fe(3+)-transferrin (Fe(3+)-TF) and Cu(2+)-ceruloplasmin (Cu(2+)-CP) pools, of superoxide dismutase activity and the inhibitory activity of alpha 2-macroglobulin in blood as well as changes in synthesis rates of deoxyribonucleotides (dNTP), DNA and proteins in organs (spleen, liver, bone marrow, thymus) of mice and dogs given total body irradiation have been studied using of ESR spectroscopy, radioisotope techniques and biochemical determination of enzymatic activity. The experimental data have allowed us to reveal the sequence of organism's response reactions against irradiation and their modifications by radioprotectors. Changes in blood Fe(3+)-TF pool is one of the most informative, highly radiosensitive and rapidly reactive marker against irradiation and drug administrations. This irontransport protein controls a rate-limiting iron-dependent stage for DNA synthesis--the synthesis of dNTP, catalyzed by iron-containing ribonucleotide reductase (Fe(3+)-RR). It has been shown that time-dependent post-irradiation changes of Fe(3+)-TP pool in blood are characterized by three distinct stages: 1) the prompt increase of pool (SOS-type response) playing the important role in protecting of cell's genetic apparatus from damage; 2) the decrease of its pool within 3-18 h after irradiation resulting in the loss of Fe(3+)-RR activity in tissues of blood-forming organs that make more stronger radiation-induced damage; 3) the following phase-dependent increase in Fe(3+)-TF pool at the 2-nd, 6th, 10-17th days after irradiation due to an increase in transferrin synthesis. This increase may be considered as compensatory reaction of blood-forming organs directed at restoring blood and organ's cells. The time-dependent courses of the reactions are independent from radiation doses indicating to the universal and nonspecific response of organism against irradiation. But, the intensity of this compensatory-adaptive response at 2-nd and 6th days grows with increasing radiation dose up to lethal that, and organism's response becomes abnormal and physiologically hypertrophic. The prolonged "stressful syndrome of biochemical tense state" should be attributed to negative effects for organism, since it may result in the failure of compensatory adaptive organism's reactions and animal killing. The radioprotectors ward off the appearance of this dangerous state. Dogs with initial individual characteristics of blood which were typical for "suppressed" or "activated" states had abnormal response against irradiation by low doses 0.25 or 0.5 Gy. In these cases the intensity of response reactions of organism was essentially increased and markedly deviated from linear dose dependence. The phase-dependent increase of Fe(3+)-TF pool in blood in post-irradiation time resulted to the increase of Fe(3+)-RR activity in blood-forming organs. The key event ensuring the development of compensatory adaptive reactions is the increase of capacity of protein-synthesizing apparatus, the activation of biosynthesis of dNTP and DNA against the treatment with damaging factors.     

The effect of infrared and X-ray radiation on the production of reactive oxygen species in blood and induction of cytogenetic damage in the bone marrow of mice in vivo

The goal of the present work was to study the effect of infrared light (IRL) at a wavelength of 850 nm modulated by a frequency of 101 Hz with a mode of power 22 mW/cm2 and X-rays with a voltage of 200 kV at a dose rate of 1 Gy/min on the production of reactive oxygen species (ROS) in blood cells using luminol-dependent chemiluminescence, as well as on the induction of a cytogenetic damage in bone marrow cells of mice by the in vivo micronucleus test. The experiments performed have shown: 1) the level of the ROS production in blood of the mice exposed to IRL and X-rays at an adapting dose of 0.1 Gy reaches the peak value after 0.5 h and drops to the ROS level in untreated animals 5 h after either exposure; 2) irradiation of mice with IRL and X-rays at a dose of 0.1 Gy induces adaptive responses both in blood cells and bone marrow cells of mice. These adaptive responses were revealed only 5 h after both exposures, when the level of ROS production decreased to the ROS level in untreated animals; they are equal in magnitude and dynamics and persist up to 2 months.     

Determination of the radiosensitivity of interphase-dying cells in the thymus, spleen and bone marrow of rats by flow cytometry

The flow cytofluorometry of cells stained with a DNA-specific probe was used to determine the share of dying cells (containing less than 2C DNA) in thymus, spleen and bone marrow cells of irradiated rats. The cell death curves for spleen and bone marrow had a plateau by the 6th h, and for thymus, by the 10th h following irradiation with different doses. On the basis of the dose-response relationship the share of cells dying in the interphase was determined in each organ under study, and dose-response curves shaped. All the curves had no shoulder. Do was 3.0, 3.0 and 3.7 Gy for thymus, spleen, and bone marrow cells, respectively.     

CFU-S and haematopoietic microenvironment in mice after fractionated irradiation. A study on spleen colonies.

The paper is aimed at evaluating the quantity and quality of the haematopoietic stem cells, CFU-S, in the bone marrow and the functional effectiveness of the haematopoietic microenvironment of the spleen in two time intervals after repeated exposure of mice to doses of 0.5 Gy gamma-rays once a week (total doses of 12 and 24 Gy). After irradiation, bone marrow was cross-transplanted between fractionatedly irradiated and control mice. The parameter evaluated were numbers of spleen colonies classified into size categories. The data obtained provide evidence for a significant damage to the CFU-S, concerning both their number and proliferation ability, after both total doses used. The functional effectiveness of the haematopoietic microenvironment of the spleen was impaired only in bone marrow recipients receiving a transplant after having been exposed to a total dose of 24 Gy; this dose combined with subsequent pre-transplantation irradiation resulted in a marked suppression of cell production within the spleen colonies formed from a normal bone marrow on the spleens of fractionatedly irradiated mice.     

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.     

低水平辐射诱导的细胞遗传学适应性反应

先用0.01GY x-射线(剂量率:0.01GY/分)体外照射人、兔外周血,经不同时间后再用1.5GY X-射线(0.44GY/分)照射,发现在G_0、G_1、S和G_2期受0.01GY X-射线照射后再给大剂量照射者,其染色体畸变率明显低于单纯受1.5GY X-射线照射组(P<0.01)。这一适应性反应能持续3个细胞周期,在接受小剂量照射后超过3个细胞周期再受大剂量照射者,染色体畸变率未见减少。若在第三细胞周期以后再次给予小剂量照射,可再次诱导适应性反应。用小鼠整体小剂量照射后骨髓细胞和生殖细胞亦出现这种适应性反应。另外也探讨了不同剂量和不同剂量率的预先照射对适应性反应的影响。     

小鼠低剂量辐射损伤模型的初步研究

目的:对小鼠低剂量辐射损伤模型进行初步研究并筛选敏感检测指标.方法:实验分7组,1组为正常组,其余6组用XHA600直线加速器射线照射,每组取一部分小鼠于照射后2、4、8、16h测定红细胞(RBC)、白细胞(WBC)、血小板(PLT)和血红蛋白(HGB)含量;测定小鼠肝脏和脾脏重量及其组织中的超氧化合物歧化酶(SOD)和丙二醛(MDA)含量;剩余小鼠于4周后观察骨髓切片中血细胞变化.结果:照射后4h测定血常规,发现累积辐射0.4Gy组小鼠RBC有降低趋势,WBC、HGB显著降低,PLT显著升高;肝脏、脾脏的湿质量显著降低;小鼠肝脏组织中MDA的含量显著升高、SOD的活力显著降低;4周后小鼠骨髓细胞的病理改变与单次照射剂量相关,单次较大剂量(如0.6Gy)照射对骨髓细胞影响较大,在4周观察期不能自身恢复,而多次累积照射对骨髓细胞病理改变较小.结论:小鼠低剂量辐射损伤模型的最佳造模剂量为累积照射0.4Gy即每次照射100mGy,间隔一天,连续照射4次.     

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 recombinant human interleukin-1 beta on the repopulation of bone-marrow colony-forming cells in mice subjected to the action of radiation and burns]

The radioprotective and restorative (therapeutic) effects of human recombinant interleukin-1 beta (IL-1 beta) on the population of bone marrow CFU-S of mice, subjected to either sublethal doses of ionising irradiation itself or the same irradiation in combination with thermal burn, are investigated. Both the effects of the agent are registered under both in vitro and in vivo irradiation in semi-, syn- and allogeneic animals. If the irradiation was combined with thermal burn, the "therapeutic" effect of the agent was demonstrated at irradiation dose equal to 3.06 Gy rather than to 6.12 Gy. If the bone marrow cells were irradiated in vitro in dose 3.06 Gy with the following heat shock at 42 degrees C for 10-20 min, the "therapeutic" effect of IL-1 beta was seen only if it was added to cells before rather than after irradiation. The radioprotective effect of IL-1 beta is maintained under in vitro, as well as in vivo conditions in the allogeneic system of transplantation of the CBA donor bone marrow to the C57BL mice.     

Correlation between the duration of radiation adaptive response in bone marrow cells of mice and the dose of gamma-irradiation in vivo

The dependence between the adaptive response and adaptive dose was studied on the basis of cytogenetic damage in polychromatic erythrocytes of bone marrow cells in mice after a low dose gamma-irradiation in vivo. The adaptive response to doses of 0.1 and 0.2 Gy was found to be retained for at least two months after irradiation. However, the adaptive dose of 0.4 Gy did not induce prolonged adaptive response.     

The time-course of micronucleated polychromatic erythrocytes in mouse bone marrow and peripheral blood

The time-course of micronucleated polychromatic erythrocytes (MPCE) in mouse bone marrow and peripheral blood, induced by an acute 0.1 Gy dose of X-rays, was determined using flow cytometric analysis, which made frequent sampling possible and allowed use of a dose low enough not to affect erythroid cell proliferation. The frequency of MPCE (fMPCE) began to increase in the bone marrow at 10 h after irradiation and reached a maximum at 28 h after irradiation. In the peripheral blood fMPCE began to increase at 20 h after irradiation and peaked at about 40 h after irradiation. The time-course found is discussed on the basis of data on the differentiation of erythroid cells. The results indicate that the micronuclei registered in polychromatic erythrocytes may originate from lesions induced not only during the last cell cycle but also during earlier ones. After an acute dose of 1.0 Gy of X-rays the maximum fMPCE was delayed both in bone marrow and peripheral blood reflecting an effect on the cell cycle progression of erythroblasts.     

Phospholipid metabolism in the organs of gamma-irradiated rats

The phospholipid content and incorporation of L-3H-serine and 2-14C-glycerol into phospholipids of the liver, intestine and spleen were studied 48 hr after irradiation of rats with a dose of 8 Gy. The changes in the phospholipid content of the irradiated rat organs were induced by those in the individual phospholipids in the exposed body tissues. This is assumed to be a result of the adaptive reactions of the organism to the damaging effect of ionizing radiation.     

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.     

A Study of the Regenerative Potential of Bone Marrow Cells of Donor Mice that Carry the <Emphasis Type="Italic">egfp</Emphasis> Gene in Irradiated Mice

A study of the regenerative potential of bone marrow cells of donor mice that express the enhanced green fluorescent protein was conducted in mice irradiated at a dose of 7 Gy. Expression of this protein allowed us to carry out monitoring of the presence of donor cells in recipient blood over the entire lifespan of the recipient. The lifespan of young recipients increased by 93% after transplantation; for old recipients it increased by 15%. Total acceptance of the bone marrow, spleen, thymus, and blood of the recipient with donor bone marrow cells was demonstrated over the entire life of the recipient. Only the donor colonies were detected with the studied irradiation dose and number of transplanted cells (11.7 ± 0.4) · 10⁶ on the spleen surface. The percentage of bone marrow and spleen cells that expressed the CD117 and CD34 stem cell markers in the recipient mice was above the control level for a long period of time after the irradiation. More than half of the cells with CD117, CD34, CD90.2, and CD45R/B220 phenotypes in the studied organs were donor cells. Further detailed study of the peculiarities of the engraftment of bone marrow cells, both without preliminary treatment of recipients and after the effects of extreme factors, will allow improvement of the methods of cell therapy.     

Correlation of Plasma FL Expression with Bone Marrow Irradiation Dose

Purpose

Ablative bone marrow irradiation is an integral part of hematopoietic stem cell transplantation. These treatment regimens are based on classically held models of radiation dose and the bone marrow response. Flt-3 ligand (FL) has been suggested as a marker of hematopoiesis and bone marrow status but the kinetics of its response to bone marrow irradiation has yet to be fully characterized. In the current study, we examine plasma FL response to total body and partial body irradiation in mice and its relationship with irradiation dose, time of collection and pattern of bone marrow exposure.

Materials/Methods

C57BL6 mice received a single whole body or partial body irradiation dose of 1–8 Gy. Plasma was collected by mandibular or cardiac puncture at 24, 48 and 72 hr post-irradiation as well as 1–3 weeks post-irradiation. FL levels were determined via ELISA assay and used to generate two models: a linear regression model and a gated values model correlating plasma FL levels with radiation dose.

Results

At all doses between 1–8 Gy, plasma FL levels were greater than control and the level of FL increased proportionally to the total body irradiation dose. Differences in FL levels were statistically significant at each dose and at all time points. Partial body irradiation of the trunk areas, encompassing the bulk of the hematopoietically active bone marrow, resulted in significantly increased FL levels over control but irradiation of only the head or extremities did not. FL levels were used to generate a dose prediction model for total body irradiation. In a blinded study, the model differentiated mice into dose received cohorts of 1, 4 or 8 Gy based on plasma FL levels at 24 or 72 hrs post-irradiation.

Conclusion

Our findings indicate that plasma FL levels might be used as a marker of hematopoietically active bone marrow and radiation exposure in mice.     

载氢-纳米氧化铈微泡对小鼠造血系统抗辐射作用的分析

为探讨载氢-纳米氧化铈微泡对小鼠辐射损伤的防护作用。本研究检测载氢-纳米氧化铈微泡的表征,并将60只BALB/c小鼠随机分为正常对照组、照射对照组、载氢-纳米氧化铈微泡组。小鼠经6Gy x射线一次性全身照射(剂量率2 Gy/min)。于照射后3 d和8 d处死小鼠,检测其外周血细胞数、脾脏和胸腺指数、骨髓和脾脏组织病理学变化。结果显示,照射后3 d和8 d,与正常对照组相比,载氢-纳米氧化铈微泡组和照射对照组的白细胞均明显下降,相比照射对照组,载氢-纳米氧化铈微泡组有改善(p<0.05或p<0.01);而载氢-纳米氧化铈微泡组和照射对照组的红细胞数和血红蛋白均略有下降,但差异无统计学意义。与正常对照组相比,微泡组的胸腺指数、脾脏指数均有下降,和照射对照组相比,载氢-纳米氧化铈微泡组的胸腺指数明显改善(p<0.05或p<0.01)。照射后3 d,与正常对照组相比,照射对照组的骨髓细胞较少,存在细胞碎片,载氢-纳米氧化铈微泡组骨髓细胞数量略有减少,存在细胞核松散现象。而照射后8 d,与正常对照组相比,照射对照组的骨髓细胞几乎找不到,载氢-纳米氧化铈微泡组骨髓细胞有一定数量,存在细胞凋亡现象。本研究表明,载氢-纳米氧化铈微泡通过保护造血组织、改善造血功能,对机体起到一定的辐射防护作用。     

Mechanism of biological effect of the delta-sleep-inducing peptide includes activation of deoxyribonucleotide synthesis

To find out the mechanism of oncoprotective effects of the delta-sleep-inducing peptide, we have studied the dynamics of ribonucleotide reductase activity, which is a vital enzyme in the DNA biosynthesis, using electron paramagnetic resonance (EPR), and a concentration of low molecular mass iron complexes in the murine spleen after intraperitoneal injection of the peptide and the antitumor preparation methylnitrosourea. The data obtained give evidence on the different effects on the ribonucleotide synthesis system by the substances under study. The peptide induced significant activation of the enzyme as a consequence of activation of processes of protein synthesis. Methylnitrosourea injection leads to a decrease in the concentration of the ribonucleotide reductase active form due to destruction of the enzyme active center. The prospects of the study are discussed.     

Free thymidine in the blood serum of irradiated rats with different levels of cellular depletion of the thymus and spleen

The levels of the postirradiation thymidinemia, with an equal degree of the proceeding cell depletion of lymphoid organ tissues caused by the administration of dexamethasone and exposure of rats to 3 Gy radiation, markedly varied. Three days after the injection of the hormone, the organism responded to irradiation by an increase in the concentration of thymidine in blood serum in the same manner as intact animals did. The preirradiation with a dose of 3 Gy reduced sharply the ability of the organism to respond the repeated irradiation (after 3 days) by thymidinemia. There was a lesser increase in the thymidine concentration in the blood after the injection of dexamethasone than after irradiation inducing the same cell depletion of the thymus and spleen.     

Dose- and time-related quantitative and qualitative alterations in the granulocyte/macrophage progenitor cell (GM-CFC) compartment of dogs after total-body irradiation

The effects of single-dose total-body X irradiation (TBI) on the granulocyte/macrophage progenitor cell (GM-CFC) population in bone marrow and blood of dogs were studied for dose levels of 0.78 and 1.57 Gy up to 164 days after irradiation. The blood GM-CFC concentration per milliliter was depressed in the first 7 days in a dose-dependent fashion to 5-16% of normal after 0.78 Gy and to between 0.7 and 5% after 1.57 Gy. The bone marrow GM-CFC concentration per 10(5) mononuclear cells, on the other hand, was initially reduced to about 45% of the average pre-irradiation value after 0.78 Gy and to 23% after 1.57 Gy. The regeneration within the first 30 to 40 days after TBI of the blood granulocyte values and the repopulation of the bone marrow GM-CFC compartment was associated with both a dose-dependent increase in the S-phase fraction of the bone marrow GM-CFC and a dose-dependent increase in colony-stimulating activity (CSA) in the serum. The slow repopulation of circulating blood GM-CFC to about only 50% of normal even between days 157 and 164 after TBI could be related to a correspondingly delayed reconstitution of the mobilizable GM-CFC subpopulation in the bone marrow.