Developmental kinetics of hemopoietic progenitors in the avian embryo spleen

By means of plasma clot clonal cultures, the content of the avian spleen in granulomonocytic progenitors was studied during ontogeny. Serum-free media were used that were supplemented with growth activities produced either by embryonic fibroblasts or adult spleen cells. These two conditioned media not only permitted the growth of M-CFC, G-CFC, and GM-CFC but also F-CFU (fibroblast colony-forming units) from quail or chick embryonic spleen cells. The presence of spleen cell-conditioned medium promoted the development of large colonies of immature granulocytes. In the chick the first hemopoietic progenitors appeared at E9 and their number displayed two peaks, one at E15 and a smaller one at E18. In the quail the first progenitors were detected as early as E7 and their number peaked at E10. In this species, hemopoietic progenitors disappeared definitively before hatching while in the chick some were still present at P3. The progenitor content of the chick embryo spleen was compared to that of the bone marrow. This content remained stable during all of embryonic life, while the bone marrow exhibited a very different profile, where a sharp peak at E16 was followed by an acute decline and a stabilization at a rather low level. The particular profile in the spleen speaks in favor of a special role of this organ in the development of the hemopoietic system.     

Colony formation in agar by adult bone marrow multipotential hemopoietic cells

Erythroid colony formation in agar cultures of CBA bone marrow cells was stimulated by the addition of pokeweed mitogen-stimulated spleen conditioned medium (SCM). Optimal colony numbers were obtained when cultures contained 20% fetal calf serum and concentrated spleen conditioned medium. By 7 days of incubation, large burst or unicentric erythroid colonies occurred at a maximum frequency of 40–50 per 10⁵ bone marrow cells. In CBA mice the cells forming erythroid colonies were also present in the spleen, peripheral blood, and within individual spleen colonies. A marked strain variation was noted with CBA mice having the highest levels of erythroid colony-forming cells. In CBA mice erythroid colony-forming cells were mainly non-cycling (12.5% reduction in colony numbers after incubation with hydroxyurea or 3H-thymidine). Erythroid colony-forming cells sedimented with a peak of 4.5 mm/hr, compared with CFU-S, which sedimented at 4.25 mm/hr. The addition of erythropoietin (up to 4 units) to cultures containing SCM did not alter the number or degree of hemoglobinisation of erythroid colonies. Analysis of the total number of erythroid colony-forming cells and CFU-S in 90 individual spleen colonies gave a correlation coefficient of r = 0.93 for these two cell types. In addition to benzidine-positive erythroid cells, up to 40% of the colonies contained, in addition, varying proportions of neutrophils, macrophages, eosinophils, and megakaryocytes. Taken together with the close correlation between the numbers of CFU-S in different adult hemopoietic tissues, including individual spleen colonies, the data indicate that the erythroid colony-forming cells expressing multiple hemopoietic differentiation are members of the hemopoietic multipotential stem cell compartment.     

Radioprotection of mice with interleukin-1: relationship to the number of erythroid and granulocyte-macrophage colony-forming cells

This report presents the results of an investigation of changes in the number of erythroid and granulocyte-macrophage colony-forming cells (GM-CFC) that had occurred in tissues of normal B6D2F1 mice 20 h after administration of a radioprotective dose (150 ng) of human recombinant interleukin-1 (rIL-1). Neutrophilia in the peripheral blood and changes in the tissue distribution of GM-CFC demonstrated that cells were mobilized from the bone marrow in response to rIL-1 injection. For example, 20 h after rIL-1 injection marrow GM-CFC numbers were 80% of the numbers in bone marrow from saline-injected mice. Associated with this decrease there was a twofold increase in the number of peripheral blood and splenic GM-CFC. Also, as determined by hydroxyurea injection, there was an increase in the number of GM-CFC in S phase of the cell cycle in the spleen, but not in the bone marrow. Data in this report suggest that when compared to the spleen, stimulation of granulopoiesis after rIL-1 injection is delayed in the bone marrow. Also, the earlier recovery of GM-CFC in the bone marrow of irradiated mice is not dependent upon an increase in the number of GM-CFC at the time of irradiation.     

Plasmodium berghei: influence on granulopoiesis and macrophage production in BALB/c mice

Granulocyte and macrophage progenitor cells forming colonies in vitro (GM-CFC) from bone marrow, spleen, and peripheral blood of BALB/c mice infected with Plasmodium berghei were cultured at various times postinfection in a viscous, 0.8% methylcellulose system. The numbers of GM-CFCs from bone marrow increased gradually during the first week of infection, reaching a maximum around the tenth day of the disease. Subsequently, a rise of GM-CFCs in cultures of nucleated cells from the peripheral blood was observed and, with some delay, in spleen cell cultures also, with a maximum around the end of the second week. After the tenth day of malaria infection a fall of colony frequency in bone marrow-derived cells took place, leading to subnormal values of GM-CFCs during the third week of infection. Subsequently, a decrease in the spleen cell cultures followed, but colony numbers did not fall to normal values. The general increase in GM-CFCs in the different organs was preceded by a rise in serum levels of colony-stimulating activity (CSA), attaining a maximum 1 week after P. berghei inoculation. During the following period the CSA levels fell and reached normal values around the seventeenth day of the disease. Chemotherapy with chloroquine started on the fifteenth day of infection, when GM-CFCs in the bone marrow have dropped to normal values, stopped their further decrease. In the spleen a gradual normalization took more than 2 weeks. A challenge infection evoked an elevation of GM-CFC numbers in the bone marrow and in the spleen during the first 10 days in only about 50% of immune mice. The reaction was immediate in some animals, but generally lower and of shorter duration than during primary infection. The results have indicated that a lethal P. berghei infection in mice caused a transient increase in production of CSA followed by a general recruitment of GM-CFCs in all hemopoietic organs.     

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.     

Effects of cyclophosphamide on murine bone marrow and splenic megakaryocyte-CFC,granulocyte-macrophage-CFC,and peripheral blood cell levels

The effect of cyclophosphamide (CY) on megakaryocytopoiesis in mice was examined with assays of megakaryocyte colony-forming cells (Meg-CFC) in bone marrow and spleen and simultaneous determinations of peripheral blood counts, after a single intraperitoneal dose (200 mg/kg) of CY. Significant rebound thrombocytosis (170% of normal) occurred at day 11 after injection with CY, although only modest preceding thrombocytopenia (70% of normal) was observed. After an initial 3–5-day period of suppression, total megakaryocyte colony-forming cells (Meg-CFC) in both bone marrow and spleen of CY-treated mice demonstrated rebound increases at 5 and 7 days, respectively, after administration of the drug. Granulocyte-macrophage colony-forming cells (GM-CFC) exhibited alterations which were similar to those of Meg-CFC, suggesting similar sensitivities of Meg-CFC and GM-CFC to CY. The increase in Meg-CFC in both bone marrow and spleen preceded development of thrombocytosis by 4–6 days. This suggests that increased platelet counts in CY-treated mice are attributable, at least in part, to alterations in feedback mechanisms which control megakaryocytopoiesis, with resultant stimulation of the megakaryocyte progenitor compartment.     

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.     

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.     

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.     

HEMOPOIETIC STEM CELL PROLIFERATION AND MIGRATION FOLLOWING BORDETELLA PERTUSSIS VACCINE

The ability of a single injection of killed, intact bacteria to effect an increase in the proliferative rate of hemopoietic stem cells was studied. The total numbers of colony forming units in bone marrow, spleen and peripheral blood as well as the proportion of CFU in cycle was assessed. Splenic CFU were observed to rise exponentially due initially to in situ proliferation and later to proliferation in bone marrow with migration via the blood to the spleen. The results are discussed in the light of current concepts of stem cell regulation.     

A model of hemopoietic stress in a lactate dehydrogenase mouse mutant with hemolytic anemia

A codominantly inherited mutation of the lactate dehydrogenase (LDH) in the C3H mouse causes a severe hemolytic anemia in homozygous mutants, whereas viability and fertility are close to normal. Investigation of multipotent hemopoietic stem cells (CFU-S), myeloid (GM-CFC) and erythroid progenitors (BFU-E, CFU-E) in femur and spleen indicates a general shift from bone marrow to splenic hemopoiesis. In terms of total body hemopoiesis, however, the BFU-E pool is 1.4- and the CFU-E pool 19-fold enlarged, whereas CFU-S and GM-CFC show little or no deviation from normal. It is concluded that this mouse mutant is an appropriate model of long-term hemopoietic stress showing that compensation in this severe hemolytic anemia is achieved primarily by an increase of the number of the most mature erythroid progenitors.     

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.     

Splenic hemopoiesis of the platypus (Ornithorhynchus anatinus): evidence of primary hemopoiesis in the spleen of a primitive mammal

The generation of blood cells has been observed in the spleen and in the bone marrow of the platypus. Hemopoiesis was found to be far more active in the spleen than in the bone marrow judging by the number of proliferating hemopoietic elements within a unit area of tissue from each organ. Granulocytes, erythroblasts, and megakaryocytes, with the related immature forms for each cell line, were noted in the spleen. In contrast, there were very few examples of immature forms of these cell lines and a complete absence of mature megakaryocytes in the bone marrow. These findings suggest that the spleen is the primary hemopoietic organ in the platypus. Since the platypus is one of two species representing the most primitive existing mammals, it seems likely that the spleen may be the primary hemopoietic organ in mammalian evolution.     

Mast cell growth factor (C-Kit Ligand) in combination with granulocyte-macrophage colony-stimulating factor and interleukin-3:in vivo hemopoietic effects in irradiated mice compared toin vitro effects

In the presence of hemopoietic cytokines such as granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-3 (IL-3), mast cell growth factor (MGF; also known as steel factor, stem cell factor, and c-kit ligand) has proven to be a potent hemopoietic regulatorin vitro. In these studies, we examined thein vivo effects of MGF in combination with GM-CSF or GM-CSF plus IL-3. Effects were based on the ability of these cytokines to stimulate recovery from radiation-induced hemopoietic aplasia. Female B6D2F1 mice were exposed to a sublethal 7.75-Gy dose of⁶⁰Co radiation followed by subcutaneous administration of either saline, recombinant murine (rm) MGF (100g/kg/day), rmGM-CSF (100g/kg/day), rmIL-3 (100g/kg/day), or combinations of these cytokines on days 1–17 postirradiation. Recoveries of bone marrow and splenic spleen colony-forming units (CFU-s), granulocyte macrophage colony-forming cells (GM-CFC), and peripheral white blood cells (WBC), red blood cells (RBC) and platelets (PLT) were determined on days 14 and 17 during the postirradiation recovery period. MGF administered in combination with GM-CSF or in combination with GM-CSF plus IL-3 either produced no greater response than GM-CSF alone or down-regulated the GM-CSF-induced recovery. These results sharply contrasted results ofin vitro studies evaluating the effects of these cytokines on induction of GM-CFC colony formation from bone marrow cells obtained from normal or irradiated B6D2F1 mice, in which MGF synergized with GM-CSF or GM-CSF plus IL-3 to increase both GM-CFC colony numbers and colony size. These studies demonstrate a dichotomy between MGF-induced effectsin vivo andin vitro and emphasize that caution should be taken in attempting to predict cytokine interactionsin vivo in hemopoietically injured animals based onin vitro cytokine effects.Abbreviations GM-CSF Granulocyte-Macrophage Colonly-Stimulating Factor - IL-3 Interleukin-3 - MGF Mast Cell Growth Factor - SCF Stem Cell Factor - rm Recombinant Murine - CFU-s Colony Forming Unit-Spleen - GM-CFC Granulocyte Macrophage Colony-Forming Cell - WBC White Blood Cells - RBC Red Blood Cells - PLT Platelets - SLF Steel Factor - G-CSF Granulocyte Colonly-Stimulating Factor - IL-1 Interleukin-1 - IL-6 Interleukin-6 - Epo Erythropoietin - CFC Colony-Forming Cell - Sl Steel - BFU-e Erythroid Burst Forming Units - s.c Subcutaneous - PEG Polyethyleneglycol - PIXY321 GM-CSF/IL-3 Fusion Protein     

Blockade of prostaglandin biosynthesis in intact mice dramatically augments the expansion of committed myeloid progenitor cells (colony-forming units-granulocyte, macrophage) after acute administration of recombinant human IL-1 alpha

Injection of human rIL-1 alpha in intact normal mice has positive and negative effects on myelopoiesis. Within 6 h postinjection, peripheral neutrophilia can be demonstrated. However, bone marrow and spleen cells capable of inhibiting CFU-granulocyte macrophage proliferation are detected between 6 and 48 h postinjection. These myelopoietic suppressor cells belong to the monocytic lineage and are identical to inhibitory cells induced by PGE2. Treatment of mice with indomethacin, a PG synthesis inhibitor, completely blocked the generation of IL-1-alpha-induced myelopoietic suppressor cells, and significantly enhanced femoral and splenic CFU-GM proliferation after a single injection of 0.4 microgram/mouse IL-1. The peripheral blood neutrophilia observed within 6 h after IL-1 injection was delayed to 18 to 24 h postinjection in indomethacin-pretreated mice. In mice treated with four consecutive daily injections of 0.4 microgram IL-1, a sustained peripheral neutrophilia was observed. IL-1 had little effect on femoral CFU-GM in these animals, however, splenic CFU-GM was increased 7- to 10-fold by 4 to 7 days postinjection. In IL-1 plus indomethacin-treated mice, sustained peripheral neutrophilia was observed although to a lesser degree than with IL-1 alone. Marrow CFU-GM were relatively unaffected, however, splenic CFU-GM were increased by 27-fold. These results indicate that the in vivo administration of IL-1 results in neutrophilia and generation of myelopoietic suppressive effects, mediated by cyclo-oxygenase pathway products. Blockade of PG synthesis by using the cyclo-oxygenase inhibitor indomethacin abrogates the myelopoietic suppressive effects associated with IL-1 administration and optimizes its myelopoietic stimulatory capacity. The inclusion of a cyclo-oxygenase inhibitor may have significant relevance to the clinical use of IL-1.     

Haemopoiesis in the beagle foetus after in utero irradiation

On day 33 of gestation, foetal beagles were irradiated in utero (0.9 Gy of 60Co gamma-irradiation, 0.4 Gy/min). Foetal haematocytopoiesis was studied during the third trimester of gestation (days 42-55). Peripheral blood nucleated cell counts were 33 per cent lower than normal on day 44 and continued to be lower until day 49, when values became higher than normal. Splenic cellularities of irradiated pups on day 44 were more than 3 times those of the nonirradiated, but thereafter they were similar to normal. Differences in haemopoietic progenitor cell activity between irradiated and normal foetuses were observed. In comparison with the other foetal tissues, the foetal liver appeared to experience greater radiation injury. For example, on day 44, the irradiated liver BFU-E, CFU-E, and GM-CFC per 10(5) cells were almost fivefold lower than normal values. Spleens of irradiated foetal beagles contained a marked increase in all haemopoietic progenitor cells (BFU-E, CFU-E, and GM-CFC) and recognizable proliferative granulocytic cells and nucleated erythroid cells. The haemopoietic activity of the irradiated bone marrow during days 42-44 was similar to that of the irradiated spleen, and compensated for the damaged liver. However, unlike the irradiated spleen, the irradiated bone marrow had decreased BFU-E activity compared with the values for the nonirradiated bone marrow during days 48-55. Until day 50, the irradiated marrow contained fewer recognizable proliferative granulocytic cells but more nucleated erythroid cells.     

Elimination of porcine hemopoietic cells by macrophages in mice.

The difficulty in achieving donor hemopoietic engraftment across highly disparate xenogeneic species barriers poses a major obstacle to exploring xenograft tolerance induction by mixed chimerism. In this study, we observed that macrophages mediate strong rejection of porcine hemopoietic cells in mice. Depletion of macrophages with medronate-encapsulated liposomes (M-liposomes) markedly improved porcine chimerism, and early chimerism in particular, in sublethally irradiated immunodeficient and lethally irradiated immunocompetent mice. Although porcine chimerism in the peripheral blood and spleen of M-liposome-treated mice rapidly declined after macrophages had recovered and became indistinguishable from controls by wk 5 post-transplant, the levels of chimerism in the marrow of these mice remained higher than those in control recipients at 8 wks after transplant. These results suggest that macrophages that developed in the presence of porcine chimerism were not adapted to the porcine donor and that marrow-resident macrophages did not phagocytose porcine cells. Moreover, M-liposome treatment had no effect on the survival of porcine PBMC injected into the recipient peritoneal cavity, but was essential for the migration and relocation of these cells into other tissues/organs, such as spleen, bone marrow, and peripheral blood. Together, our results suggest that murine reticuloendothelial macrophages, but not those in the bone marrow and peritoneal cavity, play a significant role in the clearance of porcine hemopoietic cells in vivo. Because injection of M-liposomes i.v. mainly depletes splenic macrophages and liver Kupffer cells, the spleen and/or liver are likely the primary sites of porcine cell clearance in vivo.     

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.     

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.