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.     

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.     

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.     

Effect of syngeneic lymphocytes, T immunodeficiency and the genotype of bone marrow donors on the differentiation of early and late splenic colonies

The formation of "early" (5-8 days) and "late" (12-14 days) colonies in spleen of lethally irradiated syngeneic or hybrid recipients after transplantation of bone marrow cells has been studied. The differentiation pattern did not depend on bone marrow cell donor's genotype and the donor-recipient combination. Erythroid to granulocyte colonies ratio (E/G) equals 2. Change of direction of bone marrow colony-forming units (CFU) differentiation has the same pattern at different stages of colony-formation. Under the influence of antigen-stimulated lymphocytes the granulopoiesis (E/G 0.3-0.5) dominanted. The thymectomy of adult animals leads to a predominant formation of erythroid colonies (E/G 3.5-5.1). When T-immunodeficiency is reversed with syngeneic lymphocytes, the differentiation of CFU is normalized at all stages of colony-formation. The process of differentiation of haemopoietic precursors, that form "early" and "late" colonies, is under T-lymphocyte control.     

Recovery of proliferative capacity of agar colony-forming cells and spleen colony-forming cells following ionizing radiation or vinblastine

The effects of sublethal radiation and the mitotic inhibitor, vinblastine sulphate, on the number of cells in mouse bone marrow capable upon transplantation of forming macroscopic colonies on the surface of the spleens of irradiated recipient mice (CFU) and on the number of cells capable of forming colonies in soft agar after cell culture (ACFU) were studied as a function of time after injury. The results show that ACFU are radiosensitive and vinblastine-sensitive cells, comparable in sensitivity to erythropoietin-sensitive cells. The temporal pattern of recovery following radiation of ACFU, different from that for CFU, is compatible with the concept that these are two distinct but closely related stem cell populations. The relevance of these findings to models of hematopoiesis and to studies on the precursors of macrophages and monocytes in inflammatory exudates is discussed.     

THE PROLIFERATIVE CAPACITY OF HAEMOPOIETIC COLONY FORMING UNITS IN THE RAT

After transplantation into rats lethally treated with cytotoxic chemicals both bone marrow and spleen CFU in the spleen and spleen derived CFU in the bone marrow expand with doubling times ( T _d) of approximately 18 hr. However, bone marrow derived CFU in the bone marrow have a T _d of 36 hr. Evidence obtained using tritiated thymidine in vitro and methotrexate in vivo show that the proliferation rate of bone marrow derived CFU is similar in both the bone marrow and spleen and calculations suggest that the different T _d between these two sites is due to the higher loss of CFU through differentiation in the bone marrow compared to the spleen. These findings further support the hypothesis of an environment in the spleen which favours CFU self-maintenance over differentiation with the opposite situation occurring in the bone marrow.     

Effect of erythrocyte breakdown products on mast cells and erythropoietin formation]

Experiments were conducted on CBA mice and albino rats. A study was made of the effect of erythrocyte destruction products (EDP) on the content of hemopoietic colony-forming units (CFU), differentiation of stem cells and the erythropoietin production. It was shown that 3 or 4 EDP injections to normal mice or to lethally irradiated (1000 rad) mice after the transplantation of bone marrow cells caused no changes in the CFU level of stem cells differentiation. In case of a daily (for 3 days) administration of EDP to mice before the irradiation (1000 rad) and bone marrow transplantation there was observed an increase of the colonies count in the recipients' spleen on account of the erythroid colonies. EDP injection caused no changes in the erythropoietic activity of the blood serum. A possible role of erythrocyte destruction products in the mechanism of erythropoiesis autoregulation is discussed.     

SELF-RENEWAL OF COLONY FORMING UNITS (CFU) IN SERIAL BONE MARROW TRANSPLANTATION EXPERIMENTS

The capacity of stem cells (CFU) for self-renewal was tested by transplanting normal bone marrow (primary transplantation) and bone marrow which had been subjected to one or two earlier transplantations (secondary and tertiary transplantation) into lethally irradiated syngeneic recipients. It was found that the capacity for self-renewal is diminished within the first weeks after one or more previous transplantations. This ability of stem cells recovered after a longer interval after the previous transplantation. The time required for this recovery depended upon the number of previous transplantations and amounted to more than 1 or 2 months after one or two transplantations respectively. Shortly after transplantation the CFU/nucleated cell ratio in bone marrow was below normal and its decrease was more pronounced when the bone marrow had been transplanted more often. An increase of the ratio towards normal values was observed in the course of one month after the last transplantation. Measurements of the spleen colony size after transplantation of normal and re-transplanted bone marrow indicated that CFUs from re-transplanted marrow gave slightly smaller spleen colonies than those of normal marrow.
It is concluded that the decreased self-renewal of stem cells shortly after previous transplantations is probably not due to a limitation in the number of normal mitoses they can perform, but to a loss of stem cells by transfer to the compartment of differentiating cells.     

Radioprotection by whole body hyperthermia: possible mechanism(s)

Studies were carried out to gain an insight into the mechanisms underlying WBH induced radioprotection. The plasma levels of IL-1α, IL-6, TNF-α and GM-CSF, were elevated in WBH treated mice between 2 and 6 h after treatment. The total nucleated cell count of hemopoietic tissues such as spleen, thymus, bone marrow and peripheral blood showed drastic reduction without recovery until death in mice treated with TBI. However, the nucleated cell count in the above tissues showed significant recovery after initial drop in WBH and WBH+TBI treated groups and reached to a normal level by day 7 and day 28, respectively. The total WBC and RBC count in peripheral blood recovered to a control level by day 28 after treatment. Significant number of endogenous spleen colonies were detected, 14 days after TBI in WBH pre-treated mice whereas no such spleen colonies could be detected in TBI treated group. The transplantation of bone marrow derived from control, WBH, TBI and WBH+TBI treated groups of mice to lethally irradiated mice (8 Gy) showed formation of spleen colonies only in mice which received bone marrow from control, WBH and WBH+TBI treated groups. Transplantation of the bone marrow from these groups of mice resulted in prolonged survival of lethally irradiated mice as compared to mice receiving bone marrow from TBI treated mice. These results seem to suggest that WBH induced radioprotection of mice could be due to immunomodulation manifested through induction of cytokines responsible for protection and proliferative response, leading to accelerated recovery from hemopoietic damage-a major cause of radiation induced death.     

Influence of poly-A:U, dextran sulfate and yeast RNA on the colony forming ability of bone marrow in irradiated mice]

Poly-A:U, dextran sulfate and yeast RNA were shown to increase the number of endogenous (CFU) in sublethally (525 r.) irradiated mouse spleens seemingly as a result of their mutagenic effect on proliferating CFU. The preparations had no effect on the number of exogenous colonies when injected together with bone marrow syngeneic cells transfer from intact donors. Dextran sulfate led to a 2.7 time increase in the number of endogenous colonies in unevenly irradiated mouse spleens mostly due to the CFU migration from the protected sites of the bone marrow. Poly-A:U and yeast RNA complex was ineffective in such an experiment. It is quite possible that the ability of dextran sulfate to increase the migrational potencies of the stem hematogenic cells served as one of the essential factors in the mechanism of its adjuvant activity.     

FETAL HEMOPOIESIS IN DIFFUSION CHAMBER CULTURES

The growth pattern of fetal liver (FL), normal adult bone marrow (NABM) and regenerating (post Velban treatment) adult bone marrow (RABM) colony forming units (CFU) cultured in diffusion chambers (DC) was studied. When twenty CFU were implanted into DC the recovery of CFU after 4 days with FL, NABM or RABM was 133 ± 7, 19 + 2 and 34 ± 2 CFU, respectively. The transplantation fraction of CFU from NABM decreased from 10-4% on day 0 to 6–9 % on day 4; that of FL did not change from the initial 6-2%. The growth rate of CFU derived from FL was substantially greater than that from NABM. The relative growth of FL and RABM CFU was clearly inhibited when the concentration of cells cultured was increased. Spleen colonies from FL cells before culture were larger (P < 0–005) than colonies from NABM but after 7 days of culture there was no difference between the two groups. Histological examination of spleen colonies showed that after DC culture FL and NABM CFU were differentiating along the three normal pathways. These data suggest that intrinsic differences exist between fetal and adult stem cells in the in vivo diffusion chamber culture system.     

Bone marrow colony-forming capacity in mice subjected to burn trauma]

A method of exogenous splenic colonies was applied to the study of the dynamics of the content of the colony-forming units (CFU) in the bone marrow of CBA mice to which thermal burn of the III degree of 15% of the body surface was inflicted. On the 4th and 16th days after the burn the CFU content in the bone marrow of mice decreased 1.7-2.1 times. The thymus cells of the intact mice administered simultaneously with the bone marrow of the burned mice increased, the amount of the splenic exogenous colonies formed in the recipients. The data obtained permitted to make a suggestion that not only the CFU count diminished in the bone marrow in the burned animals, but also the thymus-dependent cells necessary for normal colony formation.     

Nature of cells forming erythroid colonies in agar after stimulation by spleen conditioned medium

Erythroid colony formation in agar cultures of CBA cells was stimulated by the addition of pokeweed mitogen-stimulated C57BL spleen conditioned medium. Both 48-hour colonies ("48-hour benzidine-positive aggregates") and day 7 large burst or unicentric erythroid colonies ("erythroid colonies") developed, together with many neutrophil and/or macrophage colonies. In CBA mice, the cells forming erythroid colonies occurred with maximum frequency (650/10(5) cells) in 10- to 11-day-old yolk sac and fetal liver but were present also in fetal blood, spleen and bone marrow. The frequency of these cells fell sharply with increasing age and only occasional cells (2/10(5) cells) were present in adult marrow. A marked strain variation was noted, CBA mice having the highest levels of erythroid colony-forming cells. The erythroid colony-forming cells in 12-day CBA fetal liver were radiosensitive (DO 110-125 rads), mainly in cycle and were non-adherent, light density, cells sedimenting with a peak velocity of 6-9 mm/hr. These properties are similar to those of other hemopoietic progenitor cells in fetal tissues. The relationship of these apparently erythropoietin-independent erythroid colony-forming cells to those forming similar colonies after stimulation by erythropoietin remains to be determined.     

THE DEVELOPMENT OF FIBROBLAST COLONIES IN MONOLAYER CULTURES OF GUINEA-PIG BONE MARROW AND SPLEEN CELLS

In monolayer cultures of guinea-pig bone marrow and spleen the development of discrete fibroblast colonies takes place on days 9–12. The linear increase in the number of colonies with increasing numbers of explanted cells and the distribution of male and female cells in mixed cultures support the view that fibroblast colonies are clones. The concentration of colony-forming cells in bone marrow and spleen is approximately 10^-5. Bone marrow culture (but not spleen culture) fibroblasts are capable of spontaneous bone formation in diffusion chambers. Fibroblasts from both bone marrow and spleen cultures are inducible to osteogenesis in diffusion chambers in the presence of transitional epithelium.     

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.     

Radiosensitivity of cells-precursors of hemopoietic stroma (CFU-F) in the rat bone marrow under the effect of 60Co gamma irradiation in various conditions]

Conditions have been developed for cloning cells-precursors of rat bone marrow haemopoietic stroma, that form in culture dense and sparse fibroblast colonies (CFU-F) at a plating efficiency of 10(-4). Radiosensitivity of rat bone marrow CFU-F, with 60Co-gamma-irradiation in vitro, is characterized by the values of Do and n of 1.87 Gy and 1.4 respectively for all clones; 0.65 Gy and 6.7 for dense clones, and 4.27 Gy and 1.0 for sparse clones. This confirms the observed heterogeneity of CFU-F population consisting of highly radiosensitive and radioresistant subpopulations. The parameters of rat bone marrow CFU-F are nearly the same with irradiation both in vivo and in vitro; with in situ irradiation, the oxygen effect comes into play in a radiosensitive subpopulation of CFU-F; the OER values are 1.6, 2.6 and 0.9 for all, dense and sparse clones respectively.     

Chemical radioprotection of hemopoietic colony-forming cells: comparative effect of AET, anoxia, and urethan

The bone marrow colony-forming unit (CFU) technique of Till and McCulloch was employed to test the radioprotective effect of AET, anoxia, urethan on marrow cells irradiated in vivo. For AET and anoxia, a dose-reduction factor of 1.9 to 2.1 was found. Since the marrow cells were assayed for CFU content immediately after irradiation of the donor, the observed effect can be interpreted as a "true" radiation dose reduction. By contrast, urethan injection did not increase the survival of marrow CFU assayed immediately after whole-body x-irradiation. However, both urethan and AET afforded radioprotection of endogenous CFU content of spleen and bone marrow, but not of endogenous spleen colony count. It is concluded that the mechanism of radioprotection by urethan is fundamentally different from that of AET or anoxia.     

THE PERSISTENCE OF HEMOPOIETIC STEM CELLS IN VITRO

Cells capable of forming colonies in spleens of irradiated mice (CFU) are lost temporarily when bone marrow cells from rats or mice are maintained in culture. Rat marrow CFU go through a minimum at about 3 days after which there is a slow increase in the number of CFU in culture, reaching a maximum at 9 days. Mouse marrow CFU reach a minimum at 3 days and a maximum at 7 days. Some rat marrow CFU persist in culture for as long as 28 days.     

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.     

Epithelial entry rather than the ensuing systemic immune response determines the pathogenicity of two Salmonella enterica serovar Typhimurium strains in a mouse model

Most studies of Salmonella enterica serovar Typhimurium infection focus only on the pathogenicity of one strain. We investigated whether differences in pathogenicity of two wild-type S. Typhimurium strains; DT120 and SL1344, were related to gut invasion or the resulting immune response.Oral administration of a ten-fold lower number of SL1344 (10⁶ CFU) as compared to DT120 (10⁷ CFU) resulted in higher bacterial counts in liver and lymph nodes, and led to massive neutrophil infiltration of the spleen, while DT120 administration did not. In contrast, administration of the same dose (10³ CFU) of the two strains intravenously resulted in the same levels of bacteria and neutrophils in spleen and bone marrow. Oral administration of SL1344 led to an increase in neutrophil apoptosis in both spleen and the bone marrow and four out of five mice died before Day 8, while in DT120 mice, no increase in neutrophil apoptosis was observed and all mice survived until Day 8. This study reveals that two wild-type S. Typhimurium strains, despite evoking highly comparable immune responses upon intravenous injection, exhibit diverse pathogenicity in mice and thus suggests that differences in their invasiveness and survival during gut passage determines the success of the ensuing immune response.