RESPONSE OF THE PREOSTEOBLAST AND STEM CELL OF RAT BONE MARROW TO A LETHAL DOSE OF X-IRRADIATION OR CYCLOPHOSPHAMIDE

Following syngeneic or autotransplantation of hemopoietic tissue to a heterotopic location, bone formation has been observed to occur in the implanted tissue. the characteristics of the cell residing in hemopoietic tissue with bone forming potential (preosteoblast) are unknown. to define some properties of this cell, its response to X-irradiation and cyclophosphamide (CTX) was compared to the response of the hemopoietic stem cell. Adult, male rats were exposed to 900 R whole body X-irradiation or 220 mg/kg of intraperitoneal CTX. With either treatment the dose was sufficient to kill the animals by bone marrow failure. At intervals following the X-irradiation or CTX, hemopoietic tissue was examined for the presence of viable hemopoietic stem cells and preosteoblasts. Following X-irradiation, viable hemopoietic stem cells and preosteoblasts could not be detected. Following CTX these cells could be detected. It is suggested that in the rat CTX at 220 mg/kg, although causing death by bone marrow failure, does not reduce the population of the preosteoblast or hemopoietic stem cell as effectively as 900 R X-irradiation.     

Compensatory adjustment of hemopoietic stem cell pool of CBA mice after acute intake of 90Sr

It was investigated the functional status of stem cell pool (CFUs) of bone marrow, spleen and peripheral blood in mice (CBA) in early (1-30 days) and late (180-360 days) period after acute intake of 90Sr (29.6 kBq/g). Cumulative dose in red bone marrow due to incorporated 90Sr was 0.98-87.7 Gy. The kinetics, proliferative and differentiative potential of stem hemopoietic cells (CFUs) and productivity of hemopoietic tissues were significantly influenced by dose rate, absorbed dose and degree of suppresssion of bone marrow functions.The obtained results indicated that the sarcomogenous doses of 90Sr (29.6 kBq/g) resulted in realization of compensatory reactions in hemopoietic stem cell pool to support the life ability of irradiated animals: higher proliferative potential of CFUs and its repopulation, redistribution of cell subpopulations during differentiation and activation of spleens hemopoiesis.     

Collection of hematopoietic stem cells from canine peripheral blood and their ability to regenerate hematopoiesis]

A procedure is presented for the collection of a large number of hemopoietic stem cells from the peripheral blood of dogs by means of a single leukapheresis using the NCI-IBM Blood Cell Separator. In the course of a leukapheresis of about 285 min duration a mean of 23 x 10-9 leukocytes is collected from the blood. The hemopoietic stem cells among such separated leukocytes initiate repopulation of bone marrow within 10 days after whole body X-irradiation with 1200 R. The cell numbers in a defined histological section of femoral bone marrow are evaluated 9 to 10 days after irradiation and subsequent autologous transfusion of 6.72 x 10-9 separated mononuclear leukocytes. The results indicate that the bone marrow cell numbers of transfused dogs are significantly greater than in dogs given only 1200 R and reach a level of approximately 49% of the normal value. Possible ways of increasing the yield of hemopoietic stem cells from the peripheral blood will be considered.     

Stem cells from peripheral blood and bone marrow: a comparative evaluation of the hemopoietic potential in the dog

The kinetics and pattern of hemopoietic recovery after supralethal total-body irradiation (TBI) were compared after transfusion of cryopreserved autografts derived from peripheral blood and bone marrow. Fractionated TBI was given in three doses of 6 Gy each at intervals of 48 h. Grafts of peripheral blood mononuclear cells (MNC) were collected by means of continuous-flow centrifugation and by using the mobilizing agent, dextran sulphate. Autografts were adjusted to contain equal numbers of committed progenitor cells (CFU-GM). Dogs grafted with blood-derived MNC (group A) and with MNC from bone marrow (group B) all received about 1 X 10(5) CFU-GM per kg body weight. In all dogs consistent hemopoietic engraftment was achieved. Comparing the pattern of regeneration of the granulocytes, group A dogs showed a significant regeneratory advantage over group B dogs, particularly during the first 20 days after transplantation. Lymphoid recovery was more rapid in group A until day 14. In both groups, blood lymphocytes remained below normal values beyond day 100. The regeneration patterns of the platelets and reticulocytes revealed no significant differences. These results are in agreement with the hypothesis that there are differences in the relationship between CFU-GM content and hemopoietic potential of autografts from different sources.     

The action of azimexone on the cells of the hemopoietic system in mice,especially after damage with X-rays

Mice were exposed to single doses of whole body X-irradiation (1 - 2 - 4 Gy) or were treated with sulphur mustard (15 mg/kg body weight i.p.). This treatment caused a reduction of the pluripotent stem cells in the bone marrow, of the total count of nucleated bone marrow cells in the femora and of the WBC in the peripheral blood. The size distribution of the bone marrow cells showed three separate peaks. From the histological examination of the bone marrow of X-irradiated mice it was deduced that the first peak represents erythrocytes, the second lymphocytes and the third peak the precursors of red and white blood cells. Multiple doses (25 - 50 - 100 mg/kg body weight) of azimexone, an immunomodulating substance, led after moderate doses of X-rays (2 Gy) or sulphur mustard to a more rapid recovery of the various parameters. In particular a stimulant action of azimexone on the pluripotent stem cells of mice not subjected to the injurious agents could also be demonstrated.     

State of several rat hematopoietic organs following total and subtotal irradiation and after bone marrow autotransplantation]

Hemopoiesis was studied in rats after x-ray irradiation. Lethal doses of 800--820 R were applied totally, with screening the shin and with subsequent autotransplantation of bone marrow taken from noninjured hemopoietic tissue. Survival of the animals and status of hemopoietic organs (quantitative indices of the peripheral blood, bone marrow and the spleen, as well as morphological changes in hemopoietic organs) served as tests. All totally irradiated animals died by the 20th day, the 30th day in the group of screened animals 32% survived, in the group with autotransplantation of bone marrow--62%. According to the indices studied restoration of hemopoiesis proceeded more quickly and completely in the group with autotransplantation of bone marrow and somewhat slower in the group with screening the shin (but without autotransplantation); this was accompanied by repopulation of bone marrow comparing with the totally irradiated animals. Restoration of the hemopoietic organs was followed by a comparatively rapid increase in the number of myeloid cells, while the number of lymphoid cells increased more slowly.     

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.     

Early and late effects in the bone marrow of mice following 2 Gy (6 MeV) neutron irradiation

Summary Following 5 Gy gamma irradiation, residual damage in bone marrow persisted up to one year and was ascribed to genetic defects in hemopoietic stem cells (von Wangenheim et al. 1986). To see whether high LET radiation is more efficient in inducing late effects, mice were whole-body irradiated with a single dose of 2 Gy neutrons ( = 6 MeV) and femoral cellularity, CFU-S number, proliferation ability of bone marrow cells (PF) and the compartment ratio (CR), i.e. the splenic 125-iodo-deoxyuridine incorporation per transfused CFU-S were measured up to one year after the radiation insult. Within 12 weeks, femoral cellularity, PF and CR recovered to control or near-control level, whereas CFU-S numbers remained significantly below control. No further recovery was observed. On the contrary, PF and CR deteriorated again after 12 and 26 weeks, respectively. CFU-S per femur tended to decrease as well. Thus it is demonstrated that a single dose of 2 Gy 6 MeV neutrons causes significant injury in function (PF) and structure (CFU-S numbers, CR) of bone marrow which persisted up to one year. While this residual injury can be attributed to genetic defects in hemopoietic stem cells, its increasing expression is probably due to late evolving damage in microenvironmental cells. The RBE of 6 MeV neutrons for the introduction of late effects in the bone marrow is in the range of 3.     

Periarteritis nodosa in rats treated with chronic excess sodium chloride (NaCl) after X-irradiation

Five-week-old male Crj:CD (SD) rats were treated with excess sodium chloride after abdominal X-irradiation. The gastric regions of the rats were irradiated with a total dose of 20 Gy given in two equal fractions separated by 3 days. After X-irradiation, animals were fed a diet containing 10% sodium chloride. Red blood cell anemia appeared 22 weeks after the last irradiation. By gross observation, the mesenteric arteries became reddish in color, and bead- or lead pipe-like nodular thickenings were present. Microscopically, these nodularly thickened mesenteric arteries showed fibrinoid necrosis with massive inflammatory infiltration including eosinophils and neutrophils. In more advanced lesions, elastica interna and externa and medial smooth muscle cells disappeared completely and were replaced by granulation tissue. In old lesions, arterial walls were markedly thickened with fibrous or fibromuscular tissue. These findings were quite similar to those of the human periarteritis nodosa. These arterial lesions could not be found in the rats with X-irradiation only, sodium chloride only, or in nontreated animals. This study demonstrates X-ray-induced, NaCl-promoted periarteritis nodosa-like lesions in rats.     

Effects of a murine mammary tumor on in vivo and in vitro hemopoiesis

The effects of an autologous transplanted mammary tumor (RIII-T3) on hemopoiesis in RIII mice are described. Tumor-bearing animals died 30 to 40 days after inoculation and displayed splenomegaly, extreme neutrophilia, and moderately increased monocyte levels in the spleen, peripheral blood, and bone marrow. The precursors of neutrophils and monocytes, granulocyte/macrophage colony-forming cells (GM-CFC) were elevated in the spleen, bone marrow, and peripheral blood. RIII-T3-conditioned medium stimulated bone marrow GM-CFC and caused the myelomonocytic cell line, WEHI-3B, to differentiate in vitro. The conditioned medium did not stimulate erythroid, megakaryocyte, or eosinophil colony formation. When conditioned medium was fractionated, two peaks of activity corresponding to GM-CSF and G-CSF were observed, suggesting that the extreme neutrophilia observed in tumor-bearing animals may result from chronic exposure of the hemopoietic system to these hemopoietic hormones.     

Effect of ionizing radiation on the synthetic activity of blood system cells in ground squirrels in different physiological states of animals

The functional (synthetic) activity of blood lymphocytes and bone marrow haemopoietic cells in ground squirrels during the annual cycle as well as in hibernating and awaken animals in winter have been studied by fluorescent microspectrometry. The effect of ionizing radiation on animals in different functional states of the hibernation-arousal bout was investigated too. It was shown that the synthetic activity (parameter alpha) in blood lymphocytes was minimal in hibernating state in winter and maximal in active euthermic spring animals, then slightly decreased in June and more considerably decreased in the prehibernating autumn period. In awake animals in winter, the values of parameter alpha reached the same values as in summer. The changes of parameter alpha in bone marrow haemopoietic cells were essentially the same: the minimal values were observed in the prehibernation autumn period and in awake animals in winter the alpha values were slightly higher than in active euthermic animals in summer. The maximal synthetic activity in bone marrow haemopoietic cells in active euthermic spring animals is due mainly to cells in G1-G2 phases of the cell cycle. The decrease of the synthetic activity in summer is a result of the cell transition from G2 to mitosis and transition of a part of cells to G0 When investigating the hibernation-arousal bout in ground squirrels in winter, during arousal, we found two stages considerably differing in both the values of parameter alpha in bone marrow haemopoietic cells and the number of blood cells. The synthetic activity and the total number of blood and bone marrow cells in ground squirrels irradiated in the state of deep hibernation did not differ significantly from the state of non-irradiated hibernating animals. The negative effect of radiation appeared upon the arousal of these animals but it was expressed to a lesser degree in comparison with the animals irradiated in the active state. It was found that the acute irradiation of animals during arousal from hibernation in the second stage caused the most pronounced functional inactivation and cell death. The physiological state of ground squirrels subjected to ionizing irradiation at different phases of the hibernation-arousal bout plays a determining role in the changes of the qualitative and quantitative characteristics of blood system cells. Thus, the hypometabolic state of ground squirrels in hibernation is a factor of protection from the action of ionizing radiation on the organism and the immune system.     

The study of mechanisms of radioprotective action of indometofen n hematopoietic stem cells in mouse long-term bone marrow cultures

The influence of indometophen (an analog of tamoxiphen) on the dynamic content and the proliferative activity of CFUs (colony-forming units) and CFU-GM (granulocyto-macrophages precursors) and the level of colony-stimulating factor (GM-CSF) in mouse long-term bone marrow cultures were studied for 4 weeks after administration. Five days after indometophen injection the long-term cultures were exposed to irradiation with a dose of 2 Gy and on the time course of postirradiation recovery haemopoietic precursors cells and dynamic release of GM-CSF in the culture supernatants were examined. The data of this report suggest that the mechanisms responsible for the radioprotective action of indometophen may be associated both with its direct effects on the proliferation and differentiation of hemopoietic cellular precursors and with the stimulation of release of growth-differential factors by hemopoietic microenvironmental elements.     

大鼠异基因骨髓移植急性移植物抗宿主病模型的建立

目的建立较稳定的异基因骨髓移植急性移植物抗宿主病动物模型,为异基因骨髓移植后的急性移植物抗宿主病（aGVHD）的相关研究提供实验参照。方法以雄性SD大鼠为供鼠,雌性Wistar大鼠为受鼠,受体大鼠随机分成A、B、C、D、E 5组,移植当天所有受鼠均接受8.5 GY的全身照射（TBI）,于照射后4～6 h内,A组回输等量培养液,B组经尾静脉输注供鼠骨髓细胞（2×10^8个/kg）,C、D、E组分别回输供鼠骨髓细胞（2×10^8个/kg）＋不同比例的脾细胞。观察各组大鼠生存期、外周白细胞计数、及有无aGVHD的临床及病理表现。结果A组大鼠于15d内全部死亡,外周血白细胞计数明显减低,骨髓病理示造血组织减少,提示死于造血衰竭。B、C、D、E组大鼠外周血白细胞计数均有明显恢复,B组大鼠8只存活超过50 d,C、D、E组大鼠均于50 d观察期内死亡,并有aGVHD的临床表现及病理表现,但C组大鼠aGVHD的程度较轻且时间不集中,其中D、E组大鼠可于相对集中的时间内观察到典型aGVHD临床及病理。结论TBI预处理的方式是可行的,单纯输入异基因骨髓细胞不能引起明显的aGVHD,骨髓细胞与脾细胞1∶1及1∶1.5混合组均可作为异基因骨髓移植后理想的aGVHD动物模型。     

Combination effects of chronic cadmium exposure and gamma-irradiation on the genotoxicity and cytotoxicity of peripheral blood lymphocytes and bone marrow cells in rats

This work investigated the effects of chronic cadmium (Cd) exposure combined with γ-ray irradiation on the cytotoxicity and genotoxicity of peripheral blood cells and bone marrow cells in rats. Results showed that when the rats were exposed to low dose (LD) Cd of 0.1mg CdCl?/(kgd) for 8 and 12 weeks, the Cd concentration in blood reached to 135-140 μg/L and no toxic effects on peripheral blood lymphocytes, white blood cells (WBC) and granulocyte-monocyte (GM) progenitor cells were observed except polychromatic erythrocytes (PCE) of bone marrow. Moreover, this chronic LD Cd exposure significantly decreased irradiation-induced micronucleus (MN) formation and hypoxanthine-guanine phosphoribosyl transferase (hprt) mutation in lymphocytes and PCE, while the combination of LD Cd exposure and irradiation induced the additive metallothionein (MT) protein expression in bone marrow cells. When the rats were exposed to a high dose (HD) Cd of 0.5mg CdCl/?(kgd) for 8 and 12 weeks, the blood Cd level approached to 458-613 μg/L and an inflammatory response was induced, meanwhile, MN formation and hprt mutation were markedly increased, and the ratio of PCE/NCE (normochromatic erythrocyte) was significantly decreased. Furthermore, when the rats were exposed to HD Cd plus 2 Gy irradiation, additive toxic effects on MN formation, hprt mutation, PCE damage and GM progenitor cell proliferation were observed, while this combination treatment resulted in an obvious reduction of MT protein compared to HD Cd group. In conclusion, chronic exposure to LD Cd induced the adaptive response to irradiation in the genotoxicity of peripheral blood lymphocytes and PCE of bone marrow by the up-regulation of Cd-induced MT protein, but the combination of HD Cd exposure and irradiation generated the additive effects on the cytotoxicity and genotoxicity in peripheral blood lymphocytes and bone marrow cells.     

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.     

Heterologous antiserum to rat lymphohemopoietic precursor cells.

Lymphohemopoietic precursor cells in rat bone marrow are members of a subset of lymphocyte-like cells that bears the bone marrow lymphocyte antigen (BMLA) and that lacks antigens present on peripheral B and T cells. This was demonstrated by two experimental approaches. In the first, bone marrow cells with the potential to form hemopoietic colonies in spleen (CFU-S), to repopulate lumphoid tissues and blood, and to rescue lethally irradiated recipients were enriched approximately 10-fold by a fractionation procedure designed to isolate a "null" population of bone marro lymphocytes. In the second approach, the lymphohemopoietic precursor cell activity in bone marrow was completely abrogated by opsonization with rabbit antiserum (ALSBM) raised against this "null" population of bone marrow cells. Precursor cell activity was not affected by treatment with antiserum to T and B cells. Quantitative cross-absorption studies showed that the antigen detected by ALSBM on lymphohemopoietic precursor cells had the same cellular distribution as did the previously described bone marrow lymphocyte antigen. It is likely that this antigen is present both on pluripotent stem cells and on committed progenitors of the myelocytic, erythrocytic and lymphocytic series.     

Comparison of direct and indirect radiation effects on osteoclast formation from progenitor cells derived from different hemopoietic sources

Hemopoietic stem and progenitor cells from different sources differ in radiosensitivity. Recently, we have demonstrated that the multinucleated cell responsible for bone resorption and marrow cavity formation, the osteoclast, is in fact of hemopoietic lineage. In this investigation we have studied the radiosensitivity of osteoclast formation from two different hemopoietic tissues: fetal liver and adult bone marrow. Development of osteoclasts from hemopoietic progenitors was induced by coculture of hemopoietic cell populations with fetal mouse long bones depleted of their own osteoclast precursor pool. During culture, osteoclasts developed from the exogenous cell population and invaded the calcified hypertrophic cartilage of the long bone model, thereby giving rise to the formation of a primitive marrow cavity. To analyze the radiosensitivity of osteoclast formation, either the hemopoietic cells or the bone rudiments were irradiated before coculture. Fetal liver cells were found to be less radiosensitive than bone marrow cells. The D0, Dq values and extrapolation numbers were 1.69 Gy, 5.30 Gy, and 24.40 for fetal liver cells and 1.01 Gy, 1.85 Gy, and 6.02 for bone marrow cells. Irradiation of the (pre)osteoclast-free long bone rudiments instead of the hemopoietic sources resulted in a significant inhibition of osteoclast formation at doses of 4 Gy or more. This indirect effect appeared to be more prominent in the cocultures with fetal than with adult hemopoietic cells. Furthermore, radiation doses of 8.0-10.0 Gy indirectly affected the appearance of other cell types (e.g., granulocytes) in the newly formed but underdeveloped marrow cavity. The results indicate that osteoclast progenitors from different hemopoietic sources exhibit a distinct sensitivity to ionizing irradiation. Radiation injury to long bone rudiments disturbs the osteoclast-forming capacity as well as the hemopoietic microenvironment.     

Reinstatement of precipitated narcotic withdrawal hypothermia in the rat

Withdrawal hypothermia can be induced in rats by injection of naltrexone 72 h after subcutaneous implantation of a morphine pellet. At 45 days after implantation the same dose of naltrexone is without effect on body temperature and the animals are normally sensitive to the hypothermic effect of acute morphine administration. This acute administration of morphine re-sensitizes the animals to naltrexone so that administration of the antagonist again causes withdrawal hypothermia. These results are consistent with the view that narcotic dependence can be reinstated in previously dependent, but not naive, animals by acute administration of the narcotic.     

Proliferation activity of stromal stem cells (CFU-f) from hemopoietic organs of pre- and postnatal mice

Stromal stem cells (CFU-f assay) from hemopoietic organs of fetuses, in contrast to adult animals, exhibit a high proliferation activity. This implies that these CFU-f are radiosensitive and potential target cells after radioactive contamination of fetuses. Furthermore, the percentage of CFU-f in DNA synthesis is correlated with the hemopoietic activity in liver, spleen, and bone marrow. As hemopoiesis starts, high numbers of CFU-f are in S phase. In fetal liver, spleen, and bone marrow, values of 70, 43, and 58%, respectively, are reached. As hemopoietic activity decreases in liver and stabilizes in spleen and bone marrow, mitotic activity of these stromal stem cells becomes undetectable.     

Inhibition of the endocrine function of the rat thymus by x-irradiation

Whole-body X-irradiation of rats caused inhibition of endocrine function of thymus. The effect was a function of radiation dose and time after irradiation. 72 h following irradiation with doses of 6 and 8 Gy the thymus hormone content of blood serum fell down the level registered in the thymectomized animals. Cellularity of the thymus and spleen concurrently decreased. The kinetics of spontaneous chemiluminescence of blood serum, thymus and spleen cells characterized the hypersecretion of glucocorticoids in response to radiation activation of lipid peroxidation in radiosensitive rat organs.