Cloning stem cells in the bone marrow of irradiated mice]

Different amount of intact or irradiated bone marrow from syngenous donors was administered to mice irradiated with a lethal dose. There was revealed a linear dependence of the number of the 8-9-day colonies grown in the bone marrow of the femur on the amount of the administered cells, and an exponential dependence on the irradiation dose. Regularity of the stem cell cloning in the bone marrow was analogous to such in the spleen. Radiosensitivity of the colony-forming units (CFU) differed depending on the site (the spleen, the bone marrow) of their colony formation. The CFU settling in the marrow proved to be more radioresistant (D(0) equalled 160-200 P) in comparison with the CFU settling in the spleen (D(0) constituted 80-100 P). It is supposed that a different radiosensitivity of the CFU was caused by the presence of heterogenic population of the stem cells and also by specific peculiarities of the organ (the spleen, the bone marrow) in which the colonies formed.     

Isolation of murine pluripotent hemopoietic stem cells in the Go phase

A method to purify pluripotent hemopoietic stem cells in the Go phase from mouse bone marrow was established. Bone marrow cells from 5-fluorouracil (5-FU)-treated mice were fractionated by Percoll density gradient. The cells with density between 1.063 and 1.075 were further separated into wheat germ agglutinin (WGA)-positive and -negative cells using fluorescent-activated cell sorter (FACS) after staining with fluorescein isothiocyanate-conjugated WGA (FITC-WGA). An assay for spleen colony-forming units (CFU-S) revealed that the WGA-positive cells (1 X 10(6)) produced 1380 CFU-S (about 150 times of the number in the original bone marrow cells) on day 12 (but no CFU-S on day 8), whereas the WGA-negative cells produced no CFU-S. Thus, the stem cells in the Go phase are found to be enriched 150 times in 5-FU-treated WGA-positive cells.     

The in vitro radiosensitivity of hemopoietic stem cells from control and preirradiated infant mice

Summary The radiosensitivity of hemopoietic stem cells isolated from infant mice (6 or 9 days of life), of infant preirradiated mice (exposed to 126 rad on day 6 and assayed at day 9 of life) and of adult C57/B1 mice was assayed on the basis of their capacity to form spleen colonies and to incorporate iododeoxyuridine after transplantation into heavily irradiated hosts. Stem cells of infant non-irradiated mice have a D₀ of 115 rad compared to 72 rad for adult mice whereas the D₀ of preirradiated infant mice has diminished to 80 rad. No significant difference in D₀ was seen between spleen and bone marrow cells or between total cells and cells not sensitive to³H-thymidine. It is postulated that this sensitization of stem cells caused by a preirradiation is responsible for the greater mortality of infant mice after fractionated exposure compared to a single one.     

THE ROLE OF BONE MARROW OF X-IRRADIATED MICE IN THYMIC RECOVERY

The influence of the bone marrow on the repopulation of the thymus in X-irradiated mice has been investigated.
It was observed that the thymus and a certain population of bone marrow lymphocytic cells were repopulated in parallel in a cyclic fashion. This occurred either after a single exposure of mice to 400 R or after serial weekly X-ray treatments with 170 R. Lethally irradiated recipients which were grafted with bone marrow cells obtained 12-24 days after four weekly irradiations of donor mice with 170 R also exhibited a cyclic repopulation of both the thymus and the bone marrow lymphocytic population. In contrast, mice which were transplanted with bone marrow cells from unirradiated donors, containing an equal number of stem cells (CFU), exhibited a continuous rather than a cyclic recovery of both cell populations. the bone marrow stem cells of mice recovering from X-irradiation were found to have a decreased proliferative activity, since they produced significantly smaller spleen colonies in lethally irradiated recipients than marrow cells from unirradiated mice.
The results were interpreted as indicating that the bone marrow lymphocytic cells may act as thymic precursor cells and that thymic lymphopoiesis is dependent on the presence of such cells. Evidently, the production of lymphocytic cells will decrease when the stimulus for granulocyte production increases due to the limited proliferative activity of the surviving bone marrow stem cells after irradiation. This may result in a cyclic variation of the production of bone marrow lymphocytic cells and it follows that thymic lymphopoiesis will run parallel.     

Diffusion chamber and spleen colony assay of murine haematopoietic stem cells

Mouse bone marrow cells have been cultured in diffusion chambers and their capacity to form spleen colonies in irradiated mice investigated after different culture periods. The number of spleen colony-forming units (CFU) in the chambers decreased during the first day of culture. The number then increased rapidly to a level significantly above the original chamber value on the third to fifth day of culture. By that time large numbers of granulocytes and macrophages had also appeared. Histological examination of spleen colonies showed that prior culturing did not alter the ratio between the different types of colonies. Cultured bone marrow cells which were transferred to new chambers retained granulopoietic capacity. This capacity increased between the first and second day of primary culturing. At this time hydroxyurea injections to chamber hosts revealed that the progenitor cells were proliferating. The results show that the granulopoietic progenitor cells of the chambers are stem cells, and that one progenitor cell type is identical with the CFU.     

MOBILIZATION OF HAEMOPOIETIC STEM CELLS (CFU) INTO THE PERIPHERAL BLOOD OF THE MOUSE; EFFECTS OF ENDOTOXIN AND OTHER COMPOUNDS

Factors affecting the circulation of haemopoietic stem cells (CFU) in the peripheral blood of mice were investigated. I.v. injection of sublethal doses of endotoxin, trypsin and proteinase appeared to raise the number of CFU per ml blood from about 30–40 to about 300–400 or more within 10 min. The effect was smaller when smaller doses of the substances were injected. After this initial rise the number of circulating cells returned to normal in a few hours. Following endotoxin there was a second rise which started 2–3 days after injection and attained a peak on the 6th–7th day. The first rise is explained as a mobilization of stem cells from their normal microenvironments into the blood stream; the second rise is considered to reflect proliferation of CFUs in the haemopoietic tissues. The spleen seems to be acting as an organ capturing CFUs from the blood and not as a source adding stem cells to the blood.
The early mobilization of CFU after endotoxin injection did not coincide with a mobilization of neutrophils. The number of circulating band cells was increased during the first hours.
The importance of 'open sites'in the haemopoietic tissue for capturing CFUs was studied by emptying these sites through a lethal X-irradiation and injecting normal bone marrow cells. When a greater number of syngeneic bone marrow cells was injected intravenously, the level of circulating CFU in irradiated mice was slightly lower than the level in unirradiated mice during the first hours.     

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.     

Mechanisms of lymphocytic choriomeningitis virus-induced hemopoietic dysfunction.

Results of this study showed that lymphocytic choriomeningitis virus infection causes a marked activation of natural killer (NK) cells not only in the spleen but also in the bone marrow. This activity reached its peak at about day 3 of infection and declined after days 6 to 7. Enhanced NK cell activity was found to correlate with decreased receptivity for syngeneic stem cells in bone marrow and spleen, with the notable exception that decreased receptivity persisted longer in bone marrow. Treatment of infected recipients with anti-asialo GM1 (ganglio-N-tetraosylceramide) significantly increased the receptivity for syngeneic hemopoietic cells. These findings are consistent with the hypothesis that NK cell activation causes rejection of syngeneic stem cells, thus resulting in hemopoietic depression. To understand the mechanisms behind the prolonged decrease in bone marrow receptivity (and bone marrow function in the intact mouse) mentioned above, we followed the changes in the number of pluripotential stem cells (CFU-S) circulating in the peripheral blood and in endogenous spleen colonies in irradiated mice, the limbs of which were partially shielded. It was found that following a marked early decline, both parameters increased to normal or supranormal levels at about day 9 after infection. Because the bone marrow pool of CFU-S is only about 20% of normal at this time after infection, a marked tendency for CFU-S at this stage in the infection to migrate from the bone marrow to the spleen is suggested. It seems, therefore, that as NK cell activity declines, the spleen regains the ability to support growth of hemopoietic cells and the bone marrow resumes an elevated export of stem cells to the spleen. This diversion of hemopoiesis could explain both the long-standing deficiencies of the bone marrow compartment and the prolonged decrease in the receptivity of this organ.     

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.     

KINETIC PROPERTIES OF HAEMOPOIETIC STEM CELLS

A comparison of the exocolonizing and autorepopulating tests for haemopoietic stem-cell assay indicate that the ‘overshoot’in splenic colony formation, observed 12–14 days after 150 rad total-body radiation (TBR), only occurs with the auto-repopulation assay. The explanation is that the priming dose of 150 rad increases the absolute seeding rate of stem cells from the marrow. A seeding rate significantly greater than normal can ‘take’only if the spleen is available—it can expand and accommodate stem cells while the bone marrow cannot. If, however, the absolute number of colony-forming cells are decreased in the femur, a relative increase in seeding rate can take place even in the splenectomized animal. Evidence is presented concerning the different turnover states of exo- and autorepopulating stem cells (CFU) and those responsible for erythropoietic response (ERC), and the precursors of agar colony-formers.     

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.     

Appearance of foci of hematopoiesis and hematopoietic stem cells in the liver of mice following a single administration of cyclophosphane]

The nidi of hemopoiesis appeared in the liver and the lymph nodes of DBA/2, C57BL/6j and F1 (C57BL/6j X CBA) strains of mice of the 6th day after a single intraperitoneal injection of cyclophosphamide in a dose of 200 mg/kg. This process was accompanied by the appearance of stem hemopoietic cells in the liver. Their maximum number was observed on the 6th and the 9th days. On the 12th day their level decreased, but it still exceeded the one in the animals which received a suspension of normal liver cells. In myelosan exhaustion the pool of the bone marrow and splenic stem cells, the subsequent cyclophosphamide injection failed to induce the appearance of the nidi of hemopoiesis and stem cells in the liver.     

Two subpopulations of stem cells for T cell lineage

An assay system for the stem cell that colonizes the thymus and differentiates into T cells was developed, and by using this assay system the existence of two subpopulations of stem cells for T cell lineage was clarified. Part-body-shielded and 900-R-irradiated C57BL/6 (H-2b, Thy-1.2) recipient mice, which do not require the transfer of pluripotent stem cells for their survival, were transferred with cells from B10 X Thy-1.1 (H-2b, Thy-1.1) donor mice. The reconstitution of the recipient's thymus lymphocytes was accomplished by stem cells in the donor cells and those spared in the shielded portion of the recipient that competitively colonize the thymus. Thus, the stem cell activity of donor cells can be evaluated by determining the proportion of donor-type (Thy-1.1+) cells in the recipient's thymus. Bone marrow cells were the most potent source of stem cells, the generation of donor-derived T cells being observed in two out of 14 recipients transferred with as few as 1.5 X 10(4) cells. The stem cell activity of spleen cells was estimated to be about 1% of that of bone marrow cells, and no activity was found in thymus cells. By contrast, when the stem cell activity was compared between spleen and bone marrow cells of whole-body-irradiated (800 R) C57BL/6 mice reconstituted with B10 X Thy-1.1 bone marrow cells by assaying in part-body-shielded and irradiated C57BL/6 mice, the activity of these two organs showed quite a different time course of development. Spleen cells showed a markedly high level of activity 7 days after the reconstitution, followed by a decline, whereas the activity of bone marrow cells was very low on day 7 and increased crosswise. The results strongly suggest that the stem cells for T cell lineage in the bone marrow comprise at least two subpopulations, spleen-seeking and bone marrow-seeking cells. Such patterns of compartmentalization of stem cells in the spleen and bone marrow of irradiated recipients completely conform to the general scheme of the relationship between restricted stem cells and less mature stem cells, including pluripotent stem cells, which became evident in other systems such as in the differentiation of spleen colony-forming cells or of stem cells for B cell lineage.     

Effects of pre-irradiation on isogeneic and semi-isogeneic CFU growth: a study on genetic resistance.

The genetic resistance to a parental bone marrow transplant as demonstrated, when transplantation was performed early after irradiation, failed to occur if the interval between irradiation and transplantation was increased to 4 days. A similar radiation induced weakening of genetic resistance to a parental bone marrow graft in spleen and bone marrow could be demonstrated in mice, which had been irradiated with a sublethal dose at 7 days prior to the lethal irradiation and transplantation. The pre-irradiation of the recipient with a sublethal dose induced an enhancement of the growth in spleen and bone marrow of isogeneic transplanted CFU. The pre-irradiation of a single tibia also resulted in a significant weakening of the resistance in the spleen. The experiments with partial body pre-irradiation suggested a local effect of the pre-irradiation, but it could be shown that the enhanced CFU growth is not caused by an enhanced seeding of CFU in pre-irradiated bone marrow. The role of microenvironment in the phenomenon of genetic resistance is discussed.     

Genetic control of allogenic inhibition of hematopoietic stem cells]

Adult mice of C57BL/6, CBA (CBA X C57BL/6) F1, (CBA X C57BL/6) F2, F1 X CBA and F1 X C57BL/6 strains were lethally irradiated and reconstituted with a constant dose of 3-10(5) C57BL/6 bone marrow cells. At the 9th day after the bone marrow transplantation the colony count was performed in spleen of irradiated recipients. In the spleen of F1, CBA and C57BL/6 mice were registered low (0--8, intermediate (6--18) and high (22-40) numbers of colonies respectively. The segregation ratios in F2 progeny were close to 2 (low): 1(intermediate): 1(high). The segregation ratios in backcross (F1 X CBA) were close to 1(low): 1(intermediate)numbers of colonies. Backcrosses (F1 X C57BL/6) were distributed to low and high numbers of colonies with the ratio 1:1. The number of spleen colonies of males and females was the same in all segregating progeny. The results of hybrid analysis suggest that a single pair of allelic genes is involved in genetic control of allogenic inhibition, and that the resistance (manifestation of inhibition) to C57BL/6 stem cells is conferred by the dominant allele.     

Effects of chorionic gonadotropin on the hematopoietic stem cells

It was shown on the exogenic colony-forming unit (CFU) assay that the chorionic gonadotropin (CG) administration to female mice CBA in doses correlating with its concentration in different stages of woman pregnancy stimulated (depending upon the doses) the CFU formation of bone marrow, but not spleen origin. Injections of CG to the ovariectomized mice has the opposite (inhibited) effect on the CFU contents in bone marrow and spleen. CG-administration in the dose of 40 U1 to the ovariectomized and non-castrated irradiated recipients bone marrow cells stimulates (statistically significant) colonies formation. As for 200 U1 dose hormone has the similar effect only on the non-castrated animals.     

EFFECTS OF PRE-IRRADIATION ON ISOGENEIC AND SEMI-ISOGENEIC CFU GROWTH: A STUDY ON GENETIC RESISTANCE

The genetic resistance to a parental bone marrow transplant as demonstrated, when transplantation was performed early after irradiation, failed to occur if the interval between irradiation and transplantation was increased to 4 days. A similar radiation induced weakening of genetic resistance to a parental bone marrow graft in spleen and bone marrow could be demonstrated in mice, which had been irradiated with a sublethal dose at 7 days prior to the lethal irradiation and transplantation. The pre-irradiation of the recipient with a sublethal dose induced an enhancement of the growth in spleen and bone marrow of isogeneic transplanted CFU. The pre-irradiation of a single tibia also resulted in a significant weakening of the resistance in the spleen. The experiments with partial body pre-irradiation suggested a local effect of the pre-irradiation, but it could be shown that the enhanced CFU growth is not caused by an enhanced seeding of CFU in pre-irradiated bone marrow. The role of microenvironment in the phenomenon of genetic resistance is discussed.     

Protective effect of sesamol against 60Co γ-ray-induced hematopoietic and gastrointestinal injury in C57BL/6 male mice

Abstract

Protection of γ-ray-induced injury in hematopoietic and gastrointestinal (GI) systems is the rationale behind developing radioprotectors. The objective of this study, therefore, was to investigate the radioprotective efficacy and mechanisms underlying sesamol in amelioration of γ-ray-induced hematopoietic and GI injury in mice. C57BL/6 male mice were pre-treated with a single dose (100 or 50 mg/kg, 30 min prior) of sesamol through the intraperitoneal route and exposed to LD_50/30 (7.5 Gy) and sublethal (5 Gy) dose of γ-radiation. Thirty-day survival against 7.5 Gy was monitored. Sesamol (100 mg/kg) pre-treatment reduced radiation-induced mortality and resulted survival of about 100% against 7.5 Gy of γ-irradiation. Whole-body irradiation drastically depleted hematopoietic progenitor stem cells in bone marrow, B cells, T cell subpopulations, and splenocyte proliferation in the spleen on day 4, which were significantly protected in sesamol pre-treated mice. This was associated with a decrease of radiation-induced micronuclei (MN) and apoptosis in bone marrow and spleen, respectively. Sesamol pre-treatment inhibited lipid peroxidation, translocation of gut bacteria to spleen, liver, and kidney, and enhanced regeneration of crypt cells in the GI system. In addition, sesamol pre-treatment reduced the radiation-induced pattern of expression of p53 and Bax apoptotic proteins in the bone marrow, spleen, and GI. This reduction in apoptotic proteins was associated with the increased anti-apoptotic-Bcl-x and PCNA proteins. Further, assessment of antioxidant capacity using ABTS and DPPH assays revealed that sesamol treatment alleviated total antioxidant capacity in spleen and GI tissue. In conclusion, the results of the present study suggested that sesamol as a single prophylactic dose protects hematopoietic and GI systems against γ-radiation-induced injury in mice.     

Effect of a neutrophilia-inducing tumor on hemopoietic stem cells in mice

The influence of neutrophilic stimulation on hemopoietic stem cells was studied in mice with tumor-induced neutrophilia. Transfusions of marrow cells from normal and neutrophilic tumor-bearing mice into lethally irradiated normal and tumor-bearing mice were performed. The number and the erythroid:granuloid (E:G) ratio of day 7 colonies in the recipient spleens and bones as well as the size of spleen colonies of recipient animals were determined. The E:G ratio of spleen and bone marrow colonies between normal and tumor-bearing mouse recipients and the number of spleen colonies did not differ significantly in either experiment. However, spleen colonies which developed in tumor-bearing irradiated mice were significantly larger than those which developed in normal recipients in both experiments. These studies indicated that while the line of differentiation taken by hemopoietic stem cells was not affected by the neutrophilic influence of the tumor, the tumor-bearing host environment appeared to enhance proliferation of transfused stem cells and/or their descendants. The stimulators of granulocytopoiesis in this model of neutrophilia appear to act on a population of progenitor cells more mature than the stem cells capable of forming 7-day colonies in the spleen and bone marrow of irradiated recipient mice.     

Elevated Micronucleus Frequency in Bone Marrow Erythrocytes in the Progeny of Male Mice Exposed to Chronic Low-Dose Gamma Irradiation

The micronucleus frequency in bone marrow erythrocytes from the F1 progeny of male mice exposed to chronic low-dose -irradiation was determined. Male BALB/c mice were irradiated with 10, 25 and 50 cGy at dose rates of 1, 5, and 15 cGy/day and mated with unirradiated females on day 15 after irradiation. The obtained offspring had an elevated micronucleus frequency in bone marrow erythrocytes at the age of 2 months. This suggests the transmission of genome instability from damaged germ-line cells of irradiated male parents to somatic cells of the progeny.