Postradiation recovery of hemopoietic and stromal precursor cells in mice preinjected with prodigiozan]

Injection of prodigiozan to mice 24 h before irradiation caused, by the time of the radiation effect, a decrease in the number of haemopoietic cells-precursors (CFUs and CFU-HM) in the bone marrow and an increase in the functional activity of stromal cell-precursors--the haemopoietic microenvironment of transfer units (HMTU); in the spleen, the number of CFUs decreased, but the number of CFU-HM increased considerably. During the postirradiation period, the haemopoietic and stromal precursors were damaged to a lesser extent, and CFUs, CFU-HM and HMTU recovered more readily in prodigiozan-protected animals than in unprotected mice; the HMTU restoration preceded the increase in CFUs and CFU-HM levels.     

The stimulating effect of preliminary irradiation of the hematopoietic stroma with small doses on the content of hematopoietic stem cells in the bone marrow in vivo and in a long-term culture system

Preirradiation of mouse recipients with a dose of 1-2 Gy 24 and 48 h before lethal irradiation (8 Gy) made CFUs content of femur increase upon transplantation of bone marrow from exposed and intact donors. The same was with the long-term bone marrow culture: preirradiation of a stromal sublayer increased the number of CFUs in the transplanted bone marrow preirradiated with 6 Gy radiation. Retransplantation of bone marrow to irradiated donors after 5 day cultivation, a sublayer being activated, increased the number of CFUs in the femur in comparison with donors which were injected with the bone marrow from the culture without activation of the sublayer by low-level radiation.     

Kinetics of the basic sections of the hemopoietic system in radiation chimeras]

During first 3 days after mice irradiation and syngeneic bone marrow transplantation in them the number of CFUs (about 0,5% of the injected cells) was stable, although the proliferation induction began 24 hours after transplantation. As it was shown by the method of "thymidine self-distruction". Twenty four hours later all the CFUs entered the mitotic cycle. On the contrary, the commited cells (granulopoesis precursors) compartment (CFUc) enters the logarithmic growth phase since the first day. The exponential growth of the CFUs number was observed from the 4th day simultaneously with the increasing of the proliferation rate of CFUc and the beginning of the recovery of the bone marrow cells total number. In late radiation chimeras (1 month after radiation and reconstitution) the total number of CFUs was 50--70% of the initial. The other hemopoetic parameters were in the normal limits.     

Lithium-stimulated recovery of granulopoiesis after sublethal irradiation is not mediated via increased levels of colony stimulating factor (CSF)

We have previously demonstrated that lithium (Li) is an effective agent in accelerating the recovery of granulopoiesis following sublethal (2 Gy) whole body irradiation. In this report, studies are described that further define this Li-mediated recovery by measuring the levels of colony-stimulating factor (CSF) present in serum from mice administered 105 micrograms/mouse (total dose) of ultra-pure Li2CO3 for 3 days immediately following irradiation. On days 1-28 following the last lithium dose, the serum was tested for its CSF activity against both normal non-adherent derived bone marrow target cells and non-adherent marrow cells from mice administered cyclophosphamide (200 mg/kg body weight). Serum was assayed at 0.01, 0.1, 1 and 10 per cent final concentration. No significant difference in the total number of CFU-GM was observed from normal marrow using either serum from irradiated mice or lithium-treated and irradiated mice, although the irradiation did produce a 300 per cent rise in CFU-GM colonies compared to normal serum (days 4 and 10-15). From regenerating marrow, we observed a significant difference (P less than or equal to 0.01) in CFU-GM cultured with serum at 0.1 per cent concentration from irradiated and lithium-treated mice compared to irradiated mice without lithium. The presence of CSF was confirmed by its reduced activity in the presence of anti-(CSF). These results suggest (Li) may increase the sensitivity of CFU-GM to CSF, thereby producing more CFU-GM ultimately providing more circulating granulocytes.     

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.     

The regulation of hematopoietic stem cell proliferation and differentiation (CFU-S) during antigenic exposure

Hemopoietic stem cell (CFUs) proliferation is controlled by regulatory activities (stimulator and inhibitor) produced by bone marrow macrophages. Previously it has been shown that antigen administration stimulates CFUs proliferation. The data obtained in this study show the possible mechanism of antigen-induced stimulation of CFUs proliferation. 3-4 days after antigen injection bone marrow cells of BDF1 mice cease to produce inhibitory activity in contrast to similar cells of control animals. Therefore, increased CFUs proliferation in immunized mice can be due to decreased production of inhibitory activity and resulting abundance of stimulating factors. In BAlB/c mice CFUs proliferation is not changed after antigen injection and their bone marrow cells continue to synthesize inhibitory substances. Differentiation of CFUs into committed blood precursor cells may depend on the proliferation level in CFUs population since activation of CFUs proliferation in immunized BDF1 mice is accompanied by a decreased number of CFU-GM and CFU-M but an increased number of BFU-E. It should be noted that intact BAlB/c mice show a high level of CFUs proliferation similar to that of immunized BDF1 mice.     

The role of the hemopoietic microenvironment on the hemopoiesis-stimulating effect of cystamine

The influence of cystamine delivered in a radioprotective dose before and after irradiation of mouse-recipients (8 Gy) on the effectiveness of exogenous bone marrow cloning has been investigated. Cystamine administered prior to irradiation exerts a protective effect on CFUs and also causes an increase in the number of splenic colonies grown from CFUs of the transplanted bone marrow. With cystamine administered after irradiation the protective effect is absent, but the CFUs number in the femur increases in recipients transplanted with intact bone marrow in comparison with those transplanted without cystamine. It is believed, that in addition to the specific protective mechanism of action of radioprotectors, there is a nonspecific mechanism of increasing the proliferation of protected stem cells that is connected with the stimulatory effect of radioprotective agents on the haemopoietic stroma elements.     

MULTIPLICATION OF HAEMOPOIETIC COLONY FORMING UNITS (CFU) IN MICE AFTER X-IRRADIATION AND BONE MARROW TRANSPLANTATION

Kinetics of the multiplication of haemopoietic CFUs was studied in lethally irradiated mice receiving various numbers of syngeneic bone marrow cells. After transplantation of a small number of bone marrow cells, the growth rate of CFU in femoral bone marrow appeared to decrease after about 10 days after transplantation, before the normal level of CFU in the femur was attained. In the spleen it was found that the overshoot which was observed about 10 days after transplantation of a large number of bone marrow cells is smaller or absent when a small number of cells is transplanted. Experiments dealing with transplantation of 50 x 10⁶ bone marrow cells 0, 4 or 10 days after a lethal irradiation indicated that the decline in growth rate of CFUs about 10 days after irradiation could not be attributed to environmental changes in the host.
The results are explained by the hypothesis that a previous excessive proliferation of CFUs diminishes the growth rate thereafter. This hypothesis is supported by experiments in which 50 x 10⁶ bone marrow cells derived from normal mice or from syngeneic chimaeras were transplanted. The slowest growth rate was observed when bone marrow that had been subjected to the most excessive proliferation in the weeks preceding the experiment was transplanted.     

Recombinant murine steel factor stimulates in vitro production of granulocyte-macrophage progenitor cells.

The ability of murine Steel factor to promote the in vitro production of granulocyte-macrophage progenitor cells (CFU-GM) was examined in short-term liquid cultures. Bone marrow from C57BL/6J or Sl/Sld mice was placed in culture for seven days with either Steel factor alone or in the presence of IL-3. CFU-GM responsive to GM-CSF, IL-3, and CSF-1 were measured in the input population and again after 3 or 7 days in culture. Steel factor alone increased the number of all CFU-GM types as early as 3 days after culture initiation, with further increases at day 7. This effect was potentiated by the addition of IL-3. Production of CFU-GM by C57BL/6J or Sl/Sld marrow was comparable except for enhanced production of CSF-1 responsive progenitors by Sl/Sld marrow. A recombinant Sld protein was also shown to be equivalent to the wild-type protein in its capacity to promote CFU-GM production from normal bone marrow.     

Effect of continuous, whole-body gamma irradiation upon canine lymphohematopoietic (CFU-GM, CFU-L) progenitors and a possible hematopoietic regulatory population

Clonogenic assays for granulocytes-macrophages (CFU-GM) in bone marrow and for T lymphocytes (CFU-L) in peripheral blood were performed on dogs continuously exposed to 60Co irradiation (0.02, 0.04, or 0.11 Gy/day). When decreased numbers of CFU-GM were observed they correlated well with the clinical status of the dogs but were not generally associated with increasing cumulative doses of absorbed irradiation. In clinically normal, irradiated animals, decreased CFU-GM values and myeloid-erythroid ratios were observed, suggesting that chronic irradiation may affect the granulocytic series well before decreased peripheral blood values are seen. In hypocellular dogs the number of CFU-GM were significantly decreased compared to values obtained from control or clinically normal irradiated dogs, while virtually no CFU-GM were observed in the leukemic dogs. Only the CFU-GM values of the hypocellular group showed an association, e.g., a suggestion of an abortive regenerative effort, with increasing absorbed dose. Proliferative capacity of T lymphocytes (CFU-L) was not affected by either increasing absorbed irradiation or the presence of leukemia. D0 values were determined on marrow fibroblastic cells to ascertain whether a radioresistant subpopulation of stromal elements would result from continuous in vivo irradiation. No correlation was found between absorbed dose and increased D0 values. However, seven of eight dogs which developed acute nonlymphocytic leukemia displayed marrow fibroblastic cells with elevated D0 values. These radioresistant marrow fibroblastic cells were assayed for their ability to support normal granulopoiesis and found to be not significantly different from control fibroblasts.     

The action of the tumor necrosis factor (TNF) on the recovery processes of hemopoietic colony-forming cells in irradiated mice

The influence of a tumor-necrotic factor (TNF) on the CFUs population has been studied normally and after irradiation. An inhibitory effect on the pool of the seven-day and doubling of the yield of the eleven-day colonies have been observed in mice received TNF 20 h before bone marrow removal as compared with the controls. The kinetics of restoration of bone marrow cellularity and CFUs number in mouse donors treated with TNF 20 h before irradiation (5.0 Gy) has demonstrated the stimulatory effect of the agent on both indices.     

Modification of the proliferative capacity of transplanted bone marrow colony forming units by changes in the host environment

Regulation of the proliferation of transplanted colony forming units (CFUs) was investigated in lethally irradiated mice, pretreated by methods known to accelerate hemopoietic recovery after sublethal irradiation. Prospective recipients were exposed to either hypoxia, vinblastine or priming irradiation and at different intervals thereafter lethally irradiated and transplanted with bone marrow. Repopulation of CFUs was determined by counting the number of splenic colonies in primary recipients or by retransplantation. Regeneration of grafted CFUs was greatly accelerated and their self-renewal capacity increased in mice grafted within two days after hypoxia. Also the number of splenic colonies formed by grafted syngeneic CFUs as well as by C57BL parent CFUs growing in BC3F1 hosts was significantly increased. The effect was not dependent on the seeding efficiency of CFUs and apparently resulted from hypoxia induced changes in the hosts physiological environment. Proliferative capacity of grafted CFUs increased remarkably in hosts receiving vinblastine two or four days prior to irradiation. Priming irradiation given six days before main irradiation accelerated, given two days before impaired regeneration of CFUs. The increased rate of regeneration was not related to the cellularity of hemopoietic organs at the time of transplantation. The growth of CFUs in diffusion chambers implanted into posthypoxic mice was only slightly improved which does indicate that the accelerated regeneration of CFUs in posthypoxic mice is mainly due to the changes in the hemopoietic microenvironment. A short conditioning of transplanted CFUs by host factor(s) was sufficient to improve regeneration. The results might suggest that the speed of hemopoietic regeneration depends on the number of CFUs being induced to proliferate shordy after irradiation, rather than on the absolute numbers of CFUs available to the organism.     

Effect of Hyperthyroidism On Haemopoietic Stem Cell Kinetics In Mice

Changes in the pool of haemopoietic colony-forming units (CFUs) of bone marrow and spleen were studied in experiments with mice fed dried thyroid gland (TH) for 21 days, and during the 13 days that followed feeding. After HU treatment, the number of CFUs in DNA synthesis was estimated. As early as the second day of TH treatment, the pool of CFUs is gradually increased, leading to an increase in the total number of splenic and bone marrow CFUs persisting after TH treatment for the period examined. Simultaneously, the numbers of nucleated cells in the bone marrow and spleen are increased. During TH feeding and following its termination, the total number of erythrocytes and the haematocrit values did not change significantly, whereas an increased number of leucocytes was observed in the peripheral blood after TH treatment. Elevation of the proliferative activity of CFUs occurred early in the period of TH treatment, with the maximum attained by end of the first week of TH feeding. This suggests a rapid response of the haemopoietic stem cell compartment to the administration of TH hormones. the participation of humoral factors controlling CFUs compartments in the mechanism of the stimulatory effect of TH hormones on haemopoietic stem cells is discussed.     

Comparison of the reparative property of early and late CFUs after sublethal radiation injury

Restoration ability of early and late CFUs has been studied using bone marrow sublethal fractional irradiation. It has been shown that CFUs capacity for early postirradiation repair on the 11th day is sharply reduced, as compared to that of CFUs on the 8th day.     

In vitro activity of folic acid on the proliferation dynamics of human bone marrow CFU-GM in propyphenazone-induced granulocytopenia]

The in vitro action of folic acid was tested on the proliferation of bone marrow granulocyte-macrophage progenitor cells from a patient with drug-induced (propyphenazone) neutropenia in remission 20 days after the drug had been suspended. Various bone marrow cultures were prepared with standard stimulant, adding, respectively: folic acid, propyphenazone and both folic acid and propyphenazone together. Growth was tested on day 7, 12 and 19 of incubation. Under baseline culture with standard stimulant, CFU-GM growth was characterized by successive proliferation waves of various entity: the first on day 7 was very high, the second, on day 12 was rather low, and the third, on day 19 was intermediate. This behaviour is different from what is usually observed in normal subjects in steady-state, whose first (AC-A+AC-B) and second (AC-C) proliferation period are of similar entity. The prevalence of the first proliferation period in our case is interpreted as the result of a renewed granulocytopoietic activity after drug-induced bone marrow suppression. This indicates a maintained integrity of the negative-feedback mechanism of homeostatic regulation on granulocytopoietic activity. The sole addition of propyphenazone on the in vitro bone marrow cell cultures of our patient produced a reduction of those CFU-GM that had grown during the first period whereas the growth during the second and third period remained unvaried. Thus the growth peak in cultures treated with propyphenazone occurred on day 19, which seems to correspond with the necessary time for a spontaneous remission from neutropenia, clinically observed to be 20 days after suspension of the propyphenazone-containing drug.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of internal exposure to 90Sr on hematopoietic stem cells in CBA mice

After acute intake of 90Sr the changes of d-9 CFUs number in mice (CBA) bone marrow, spleen and peripheral blood were investigated. The obtained results indicated similar quantitative changes in bone marrow and spleen CFUs on exposure to the 90Sr when radiation doses did not cause the decrease in life-time (1.11 kBq/g). Sarcomogeneous doses of 90Sr (29.6 kBq/g) resulted in drastic changes of hemopoietic system: spleen haematopoiesis activation and suppression of bone marrow functions. On the first day after 90Sr injection (29.6 kBq/g) the increase in number of peripheral blood CFUs (circulating pool) was observed.     

减毒沙门氏菌介导的血小板第四因子活性片段的放射保护作用研究

目的:观察减毒沙门氏菌携带的血小板第四因子活性片段PF417 70 的放射保护作用。方法:通过口服途经喂饲小鼠携带PF4活性片段的减毒沙门氏菌,在第 2次喂饲后小鼠接受 70 0cGy全身照射,然后观察PIRES2 EGFP PF417 70 在小鼠体内的表达,并观察小鼠的造血恢复情况。结果:在小鼠的肝脏、脾脏、肾脏、小肠、外周血及骨髓均能检测到GFP的表达和转基因的整合。与对照组比较,实验组小鼠的生存期明显延长,照射后第 7d和 1 4d骨髓有核细胞数、骨髓培养的CFU GM和HPP CFC数量明显增加 (P <0 0 5 )。结论:首次应用减毒沙门氏菌SL32 61为载体来介导PF4活性片段的生物学作用,并证实通过口服途径可以保护小鼠免受放射损伤,并促进放射损伤后小鼠的造血恢复。     

The precursor hematopoietic cell: its origin in ontogeny, proliferative activity and proliferative potential

Cells responsible for repopulation of irradiated longterm cultures of murine bone marrow and capable of generating CFUs for at least 4-5 weeks after seeding referred here to as primitive hemopoietic stem cells (P-HSC) were assayed by limiting dilution analysis. During development of mice P-HSC can be detected for the first time in the liver of 12-13-day-old embryos and their number is about 10 per organ. At day 17-18 of gestation the number of P-HSC increases ten-fold; however, we could not detect the proliferation of these cells using the technique of hydroxyurea suicide. In the adult mouse P-HSC content is about 100 precursors per femur and their concentration is one P-HSC per 1-2 x 10(5) bone marrow cells. P-HSC content in the spleen is 0.5 per 10(6) cells. In vivo treatment with 5-fluorouracil or hydroxyurea (six injections every 6 h) does not alter significantly the number of P-HSC, although either treatment kills about 99% of CFUs. Several months after reconstitution of lethally irradiated mice with a "small" inoculum of bone marrow cells (0.20-0.35 x 10(6)) the number of bone marrow P-HSC was reduced as compared to that in animals reconstituted by injection of a "large" cell dose (20-35 x 10(6)). These data suggest that P-HSC have limited proliferative potential and are incapable of self-maintenance.     

Influence of IL-1 alpha and -1 beta on the survival of human bone marrow cells responding to hematopoietic colony-stimulating factors

Purified recombinant human (rhu) IL-1 alpha and IL-1 beta were evaluated for their effects on the proliferation and survival of granulocyte-macrophage (CFU-GM) and erythroid (BFU-E) progenitor cells from normal human bone marrow (BM). Using nonadherent low density T lymphocyte depleted (NALT-) BM cells cultured in the presence or absence of IL-1, CSF-deprivation studies demonstrated that IL-1 alpha or IL-1 beta by itself did not enhance the proliferation of CFU-GM or BFU-E. They did, however, promote the survival of progenitors responding to the delayed addition of media conditioned by the 5637 cell line (5637 conditioned medium), rhu GM-CSF and erythropoietin. The survival promoting effects of IL-1 alpha on CFU-GM and BFU-E were neutralized by anti-IL-1 alpha mAb added to the cultures. The survival promoting effect of IL-1 alpha did not appear to be mediated by CSF, because neither CSF nor erythroid burst promoting activity were detectable in cultures in which NALT- cells were incubated with rhuIL-1 alpha. In addition, suboptimal concentrations of rhu macrophage CSF (CSF-1), G-CSF, GM-CSF, and IL-3, which were just below the levels that would stimulate colony formation, did not enhance progenitor cell survival. Survival of CFU-GM and BFU-E in low density (LD) bone marrow cells did not decrease as drastically as that in NALT- BM cells, and exogenously added IL-1 did not enhance progenitor cell survival of CFU-GM and BFU-E in LD BM cells. However, addition of anti-IL-1 beta decreased survival of CFU-GM and BFU-E in LD BM cells. These results implicate IL-1 in the prolonged survival of human CFU-GM and BFU-E.     

The suppressive influences of human tumor necrosis factors on bone marrow hematopoietic progenitor cells from normal donors and patients with leukemia: synergism of tumor necrosis factor and interferon-gamma

The influences of human tumor necrosis factor (TNF) (LuKII), recombinant human TNF-alpha, natural human interferon-gamma (HuIFN-gamma), recombinant HuIFN-gamma, and natural HuIFN-alpha were evaluated alone or in combination for their effects in vitro on colony formation by human bone marrow granulocyte-macrophage (CFU-GM), erythroid (BFU-E), and multipotential (CFU-GEMM) progenitor cells incubated at 5% CO2 in lowered (5%) O2 tension. TNF (LuKII) and recombinant TNF-alpha caused a similar dose-dependent inhibition of colony formation from CFU-GM, BFU-E, and CFU-GEMM. Day 7 CFU-GM colonies were more sensitive than both day 14 CFU-GM colonies and day 7 CFU-GM clusters to inhibition by TNF. BFU-E colonies and CFU-GEMM colonies were least sensitive to inhibition with TNF. The suppressive effects of TNF (LuKII) and recombinant TNF-alpha were inactivated respectively with hetero-anti-human TNF (LuKII) and monoclonal anti-recombinant human TNF-alpha. The hetero-anti-TNF (LuKII) did not inactivate the suppressive effects of TNF-alpha and the monoclonal anti-recombinant TNF-alpha did not inactivate TNF (LuKII). The suppressive effects of TNF did not appear to be mediated via endogenous T lymphocytes and/or monocytes in the bone marrow preparation, and a pulse exposure of marrow cells with TNF for 60 min resulted in maximal or near maximal inhibition when compared with cells left with TNF for the full culture incubation period. A degree of species specificity was noted in that human TNF were more active against human marrow CFU-GM colonies than against mouse marrow CFU-GM colonies. Samples of bone marrow from patients with non-remission myeloid leukemia were set up in the CFU-GM assay and formed the characteristic abnormal growth pattern of large numbers of small sized clusters. These cluster-forming cells were more sensitive to inhibition by TNF than were the CFU-GM colonies and clusters grown from the bone marrow of normal donors. The sensitivity to TNF of colony formation by CFU-GM of patients with acute myelogenous leukemia in partial or complete remission was comparable with that of normal donors. When combinations of TNF and HuIFN were evaluated together, it was noted that TNF (LuKII) or recombinant TNF synergized with natural or recombinant HuIFN-gamma, but not with HuIFN-alpha, to suppress colony formation of CFU-GM, BFU-E, and CFU-GEMM from bone marrow of normal donors at concentrations that had no suppressive effects when molecules were used alone.(ABSTRACT TRUNCATED AT 400 WORDS)