Effect of myleran on murine hemopoiesis. I. Granulocytic cell line specificity of action on progenitor cells.

Time- and dose-dependent patterns of depletion and regeneration of hemopoietic progenitor cells in mouse femora and spleens following treatment with the antileukemic agent Myleran (Busulphan, MY) were studied using the murine spleen colony system and the agar gel in vitro colony system. MY was found to depress granulopoiesis selectively, as manifested by the development of marked prolonged neutropenia, hypoplasia of the bone marrow and (to a lesser degree) of the spleen, reduction of the incidence of multipotential hemopoietic progenitor cells (CFU-S) and of granulocytic progenitor cells (CFU-C) in both femora and spleens, and impairment of the capacity of CFU-S from either tissue to generate granulocytic colonies in the spleens of irradiated hosts. The severity and duration was greatest at high dose levels of MY (800 microgram). The action of MY on CFU-S was more pronounced than that on CFU-C, suggesting that MY is a cycle-independent agent. Repopulation of the CFU-C pool preceded that of the CFU-S pool. Development of neutropenia and maximal marrow hypoplasia followed the onset of depression of CFU-S and CFU-C incidence, while recovery of normal nucleated cellularity in the blood, femur and spleen preceded repopulation of the CFU-S and CFU-C pools. MY treatment resulted in transitory stimulation of colony stimulating factor (CSF) generation by the femur but had no effect on serum CSF levels. The peak of femoral CSF generation coincided with the nadir of CFU-C depression. These findings indicated that the prolonged neutropenia following MY treatment was secondary to depletion of the progenitor cell pools, that during recovery granulopoietic repopulation took precedence over self-maintenance of the hemopoietic progenitor cell pools, and that increased generation of CSF may play a role in the early phase of granulopoietic recovery.     

Erythropoietic progenitors capable of colony formation in culture: state of differentiation

The differentiated state of mouse erythropoietic progenitor cells (CFU-E), detected by their ability to form erythropoietin-dependent colonies in vitro, has been investigated. Transfusion-induced plethora was found to reduce the population size of CFU-E in both spleen and femoral marrow, which indicates that a significant number of CFU-E arise by differentiation processes that are themselves erythropoietin-dependent. Individual spleen colonies were found to be heterogeneous in their content of CFU-E, and the numbers of CFU-E per colony were not correlated either positively or negatively with the numbers of granulocyte-macrophage progenitors (CFU-C) present in the same colonies. The absence of a negative correlation between CFU-E and CFU-C indicates that the erythropoietic and granulopoietic pathways of differentiation are not mutually exclusive within individual spleen colonies. The numbers of CFU-E per spleen colony were also found to vary independently of the numbers of pluripotent stem cells (CFU-S) per colony; in contrast, as found previously, the numbers of CFU-C and CFU-S per colony were positively correlated. These results indicate that more randomizing events separate CFU-E from CFU-S than separate CFU-C from CFU-S, and are consistent with the view that CFU-E occupy a position on the erythropoietic pathway of differentiation that is more remote from the pluripotent stem cells than is the corresponding position of CFU-C on the granulopoietic pathway.     

Pluripotent (Cfu-S) and Granulocyte-Committed (Cfu-C) Stem Cells In Intact and 89Sr Marrow-Ablated S1/S1D Mice

Peripheral blood values, femur cell counts, spleen weights, pluripotent (CFU-S) and granulocyte progenitor cell (CFU-C) concentrations and total content of spleens and femurs have been evaluated in intact (non-marrow-ablated) and ⁸⁹Sr marrow-ablated S1/S1^d and +/+ mice. ⁸⁹Sr-irradiated mice were studied 6 and 11 days after the administration of ⁸⁹Sr. In intact S1/S1^d mice the femur CFU-S concentration, total femur CFU-S, femur CFU-C concentration and total femur CFU-C were 84, 54, 105 and 68% that of +/+ mice femurs respectively; the respective values for the spleens of S1/S1^d mice were 40,46,61 and 69%. These are the first simultaneous determinations of CFU-S and CFU-C concentrations, and content of spleens and marrows, of S1/S1^d and +/+ mice. In ⁸⁹Sr marrow-ablated mice, 11 days after injection of the radionuclide: (a) the total content of marrow CFU-C and CFU-S was about 1% of that found in the marrows of intact mice for both +/+ and S1/S1^d groups; (b) the spleens of +/+ mice increased in weight to 162% of the control, but the spleens of S1/S1^d mice did not increase in weight; and (c) the spleens of +/+ mice had a total content of CFU-C and CFU-S of 800% and 260% of the control, respectively, whereas the respective values for the S1/S1^d mice were 120% and 76% of the control. Thus the S1/S1^d spleen fails to compensate for marrow ablation by housing additional CFU-S and has an impaired ability to compensate by housing additional CFU-C.     

The effects of graded doses of 1 MeV fission neutrons or X rays on the murine hematopoietic stroma.

The acute radiosensitivity in vivo of the murine hematopoietic stroma for 1 MeV fission neutrons or 300 kVp X rays was determined. Two different assays were used: (1) an in vitro clonogenic assay for fibroblast precursor cells (CFU-F) and (2) subcutaneous grafting of femora or spleens. The number of stem cells (CFU-S) or precursor cells (CFU-C), which repopulated the subcutaneous implants, was used to measure the ability of the stroma to support hemopoiesis. The CFU-F were the most radiosensitive, and the survival curves after neutron and X irradiation were characterized by D0 values of 0.75 and 2.45 Gy, respectively. For regeneration of CFU-S and CFU-C in subcutaneously implanted femora, D0 values of 0.92 and 0.84 Gy after neutron irradiation and 2.78 and 2.61 Gy after X irradiation were found. The regeneration of CFU-S and CFU-C in subcutaneously implanted spleens was highly radioresistant as evidenced by D0 values of 2.29 and 1.49 Gy for survival curves obtained after neutron irradiation, and D0 values of 6.34 and 4.85 Gy after X irradiation. The fission-neutron RBE for all the cell populations was close to 3 and varied from 2.77 to 3.28. The higher RBE values observed for stromal cells, compared to the RBE of 2.1 reported previously for hemopoietic stem cells, indicate that stromal cells are relatively more sensitive than hemopoietic cells to neutron irradiation.     

LOCAL AND SYSTEMIC CONTROL OF GRANULOCYTIC AND MACROPHAGE PROGENITOR CELL REGENERATION AFTER IRRADIATION

Agar cultures of C₅₇BL bone marrow cells were used to determine colony stimulating factor (CSF) and serum CSF-inhibitor levels in C₅₇BL and BALB/c mice following irradiation. Whole-body irradiation caused an acute, dose-dependent, rise in serum CSF levels and fall in CSF-inhibitor levels. The regeneration of granulocytic and macrophage progenitor cells ( in vitro CFCs) in the femur after 250 rads whole-body irradiation was preceded or paralleled by a fall in serum CSF-inhibitors and a dramatic rise in the capacity of bone-adherent cells in the marrow ('stromal cells') to produce material with colony-stimulating activity. No comparable changes were observed in the activity of marrow haemopoietic cells during regeneration or in the lungs or spleen. A similar rise in the activity of bone-adherent cells was observed in shielded femurs during regeneration of in vitro CFCs.
Regeneration of granulocytic and macrophage progenitor cells following irradiation may be regulated by fluctuations in circulating CSF-inhibitor levels and local production of CSF within the marrow cavity.     

Radiation sensitivity of hemopoietic stroma: long-term partial recovery of hemopoietic stromal damage in mice treated during growth

We studied the ability of the hemopoietic organ stroma to recover from damage inflicted by 5 or 7 Gy gamma radiation administered during a period of stromal growth in 4-week-old mice. Irradiation resulted in an immediate depletion of femoral colony-forming fibroblastic progenitors (CFU-F) down to 10-20% of age-matched control values. A full recovery to normal numbers occurred between 120 and 240 days after irradiation and was followed by a secondary decrease 1 year after irradiation. This secondary decrease was accompanied by a decrease in the femoral CFU-S and CFU-C content. Femoral CFU-F attained normal numbers and it was demonstrated to occur from surviving CFU-F and could not be enhanced or prolonged following infusion of unirradiated bone marrow cells after irradiation. During the transient CFU-F recovery the hemopoietic stroma remained severely damaged as judged by the regenerative capacity of spleen and femur stroma after subcutaneous implantation, and the ability of the spleen to accumulate CFU-S in response to lipopolysaccharide injection. We have reported earlier that in similarly irradiated adult mice, no restoration of femoral CFU-F was observed. This difference between 4-week-old and adult mice could not be explained by a difference in in vitro radiosensitivity of CFU-F or in their in vivo regeneration kinetics following irradiation and subsequent lipopolysaccharide injection. We conclude from these observations that the recovery kinetics of the CFU-F population is different in young and adult irradiated mice, infused CFU-F do not contribute to CFU-F regeneration in an irradiated femur, CFU-F are not the sole determinants of stromal regeneration in femur and spleen following irradiation.     

Radioprotection of mice with interleukin-1: relationship to the number of spleen colony-forming units

Compared to saline-injected mice 9 days after 6.5 Gy irradiation, there were twofold more Day 8 spleen colony-forming units (CFU-S) per femur and per spleen from B6D2F1 mice administered a radioprotective dose of human recombinant interleukin-1-alpha (rIL-1) 20 h prior to their irradiation. Studies in the present report compared the numbers of CFU-S in nonirradiated mice 20 h after saline or rIL-1 injection. Prior to irradiation, the number of Day 8 CFU-S was not significantly different in the bone marrow or spleens from saline-injected mice and rIL-1-injected mice. Also, in the bone marrow, the number of Day 12 CFU-S was similar for both groups of mice. Similar seeding efficiencies for CFU-S and percentage of CFU-S in S phase of the cell cycle provided further evidence that rIL-1 injection did not increase the number of CFU-S prior to irradiation. In a marrow repopulation assay, cellularity as well as the number of erythroid colony-forming units, erythroid burst-forming units, and granulocyte-macrophage colony-forming cells per femur of lethally irradiated mice were not increased in recipient mice of donor cells from rIL-1-injected mice. These results demonstrated that a twofold increase in the number of CFU-S at the time of irradiation was not necessary for the earlier recovery of CFU-S observed in mice irradiated with sublethal doses of radiation 20 h after rIL-1 injection.     

Studies on the kinetics of hemopoietic stem cells and immune responses to the hapten-carrier conjugate.

The correlation between the kinetics of hemopoietic stem cells and immune responses to the hapten-carrier conjugate was investigated. The numbers of both pluripotent stem cells (CFU-S) and myeloid stem cells (CFU-C) in the spleen from mice immunized with the hapten-carrier conjugate were significantly greater than those of the control and the activity of colony-stimulating factor (CSF) in the serum of these mice was markedly elevated. The supernatant of short-term incubation of splenic T lymphocytes from these mice, when stimulated with carrier protein, had high levels of both activities of CSF and helper T cell factors. The study by gel chromatography showed that these factors are similar m.w. substances of 35,000 to 45,000 daltons. But analysis by ion-exchange chromatography demonstrated that they do not have identical biochemical properties. The present studies suggest that biologically active factors produced by T cells stimulated with carrier protein may induce the enhancing effect on the proliferation and differentiation of hemopoietic stem cells and immune responses to the hapten-carrier conjugate.     

Serial transplantation of p53-deficient hemopoietic progenitor cells to assess their infinite growth potential

Thirty-five years ago, Siminovitch et al. (Siminovitch L, Till JE, McCulloch EA. J Cell Com Physiol 64:23-32, 1964), using serially transplanted mouse spleens at 14-day intervals, observed a markedly progressive decline in the proliferative capacity of bone marrow (BM) cells, with the loss of clonogenicity by the fourth transplant generation. Using the same protocol, we assessed the proliferative capacity of p53-deficient mouse BM cells transplanted serially at the same 14-day intervals into lethally irradiated mice, which was a useful tool for understanding the characteristics of hemopoietic stem cells lacking solely the p53 gene function. BM cells from p53-deficient homozygous (p53(-/-)), p53-heterozygous (p53(+/-)), and wild-type (p53(+/+)) C57BL/6 mice were transplanted into lethally irradiated C57BL/6 recipients. Fourteen days later, the repopulated spleens were harvested, and 10(7)cells were retransplanted into secondary recipients. Serial transplantation was continued at 14-day intervals until hemopoietic repopulation failure. The number of heterozygous and homozygous p53-deficient spleen cells increased logarithmically up to the fourth and fifth passages, respectively, whereas wild-type spleen cells ceased to proliferate by the third passage. The number of macroscopic spleen colonies increased logarithmically until the third passage in recipients of heterozygous and homozygous p53-deficient cells, but ceased to grow by the second passage in recipients of wild-type cells. The numbers of heterozygous and homozygous p53-deficient colony forming units in spleen (CFUs-S) remained stable during the first four transplant generations, whereas that of wild-type CFUs-S decreased progressively from the first transplant generation onward. The clonogenicity of p53-deficient cells was lost when the number of CFUs-S per spleen decreased to below 10. This suggests that one out of 10 CFUs-S might be long-term repopulating cells (LTRCs), and that p53-deficient LTRCs may proliferate more rapidly than wild-type LTRCs. Longer passages that were possible in the p53-deficient groups were considered to be due to the faster cell cycle of the p53-deficient hemopoietic progenitor cells, as determined by bromodeoxyuridine incorporation with purging by UV light exposure, followed by hemopoietic colony assay (BUUV assay).     

Role of splenic stroma in the action of bacterial lipopolysaccharides on radiation mortality: a study in mice carrying the Slj allele

Slj/+ mice display a slight macrocytic anaemia due to a defect in their haemopoietic organ stroma. They have a deficient endogenous spleen colony (CFU-end) formation following sublethal doses of gamma-radiation compared with their normal +/+ littermates, which is likely to be due to the low pre-irradiation CFU-S content of the Slj/+ spleen. CFU-S in these congenic mice do not differ in their sensitivity to gamma-irradiation or stem cell-activating factor. While injection of +/+ mice with 10 micrograms of lipopolysaccharide-W (LPS) one day prior to irradiation led to a substantial increase in their survival, the survival of Slj/+ mice was only slightly increased. Irradiation induced a similar dose-related reduction in the numbers of CFU-S in the spleen and femora of LPS-injected Slj/+ mice compared to similarly treated +/+ mice when measured directly after irradiation. At Day 9 after irradiation, injection of LPS led to a significantly higher CFU-end formation and higher numbers of CFU-S and nucleated cells in the Slj/+ spleens compared to LPS-injected +/+ mice. No such differences in the radioprotective effect of LPS were observed in the +/+ and Slj/+ mice with respect to the splenic and femoral 59Fe-incorporation and the femoral CFU-S numbers at Day 9. These data strongly suggest a contribution by immigrating CFU-S to the CFU-S numbers and endogenous colony formation in at least the Slj/+ spleen after LPS injection and subsequent sublethal irradiation. The observations also imply that the splenic organ stroma may play a mediatory role in the radioprotective action of LPS. In addition, the data represent an extreme example of a lack of correlation between animal survival and haemopoietic parameters. Caution should be taken when applying endogenous colony counts as a means of screening potential anti-radiation drugs.     

A fractionation procedure of mouse bone marrow cells yielding exclusively pluripotent stem cells and committed progenitors

The cell surface phenotype of pluripotent hemopoietic stem cells (CFU-S) and committed progenitors (CFU-C1, CFU-C2, BFU-E) of mouse bone marrow was analyzed with respect to their binding of wheat germ agglutinin (WGA) and two monoclonal antibodies, anti-GM-1.2 and anti-PGP-1. Stained cells were fractionated on the basis of differences in fluorescence and light scatter intensity using a light-activated cell sorter. The 6% of the cells that bound most WGA and that also had a relatively high forward light scatter (FLS) and low perpendicular light scatter (PLS) contained nearly all stem cells (CFU-S) and progenitors. Anti-GM-1.2 stained only mature myeloid cells, not CFU-S or the in vitro colony-forming cells. Anti-PGP-1 stained all bone marrow cells in varying intensities: lymphoid cells were dull, CFU-S were intermediate, CFU-C2 were brighter, and mature myeloid cells very bright. Enrichment of progenitor cells was performed by a two-step sorting procedure. First, the 6% most WGA-binding cells with high FLS and low PLS were sorted out. A 10-15-fold enrichment of progenitors and CFU-S was obtained. Next, these cells were restained with anti-GM-1.2 or anti-PGP-1 and again fractionated on the FACS. The GM-1.2-negative cells were then another four- to sevenfold more enriched for stem cells and progenitors. Of the cells in this fraction, 95% could be assigned to a colony-forming unit. With anti-PGP-1, CFU-C2 could be partly separated from more early cells such as CFU-S and BFU-E.     

The responses of hemopoietic precursor cells in mice to bacterial cell-wall components

The influence upon differnt cellular and humoral parameters of hemopoiesis of three structurally unrelated, highly purified bacterial cell-wall components (BCWC) was investigated. The spleens of C57BL/6 mice assayed 6 days after the injection of either lipid A or outer-membrane lipoportein, but not murein, showed a marked increase in granulocyte-macrophage, eosinophil, and megakaryocyte progenitor cell levels. The number of pluripotent hemopoietic stem cells (CFU-S) also increased in the spleens of mice treated with either lipid A or lipoprotein. Similar results were obtained following the injection of lipoprotein or lipid A into CBA or C57BL/6.nu mice. Genetically anemic W^f/W^f mice were found to have spontaneously elevated numbers of splenic progenitor cells, which increased further after the injection of lipid A. The proportions of the different splenic progenitor cell types were similar in both untreated and lipid A treated W^f/W^f mice, and in normal littermate controls. When tested in vitro, unfractionated or partially purified post-lipid A serum was found to stimulate the growth of granulocyte-macrophage progenitor cells (GM-CFC), but no detectable stimulation of eosinohphil, megakryocyte, or erythroid progenitor cells was observed. The data suggest that the rise in splenic levels of the different progenitor cells is not mediated by the corresponding types of CSF, but more likely by proliferation and differentiation of CFU-S.     

Role of splenic stroma in the action of bacterial lipopolysaccharides on radiation mortality: a study in mice carrying the Slj allele

Abstract. Sl_j/+ mice display a slight macrocytic anaemia due to a defect in their haemopoietic organ stroma. They have a deficient endogenous spleen colony (CFU-end) formation following sublethal doses of gamma-radiation compared with their normal +/+ littermates, which is likely to be due to the low pre-irradiation CFU-S content of the Sl_j/+ spleen. CFU-S in these congenic mice do not differ in their sensitivity to gamma-irradiation or stem cell-activating factor. While injection of +/+ mice with 10 μg of lipopolysaccharide-W (LPS) one day prior to irradiation led to a substantial increase in their survival, the survival of Sl_j/+ mice was only slightly increased. Irradiation induced a similar dose-related reduction in the numbers of CFU-S in the spleen and femora of LPS-injected Sl_j/+ mice compared to similarly treated +/+ mice when measured directly after irradiation. At Day 9 after irradiation, injection of LPS led to a significantly higher CFU-end formation and higher numbers of CFU-S and nucleated cells in the Sl_j/+ spleens compared to LPS-injected +/+ mice. No such differences in the radioprotective effect of LPS were observed in the +/+ and Sl_j/+ mice with respect to the splenic and femoral ⁵⁹Fe-incorporation and the femoral CFU-S numbers at Day 9. These data strongly suggest a contribution by immigrating CFU-S to the CFU-S numbers and endogenous colony formation in at least the Sl_j/+ spleen after LPS injection and subsequent sublethal irradiation. The observations also imply that the splenic organ stroma may play a mediatory role in the radioprotective action of LPS. In addition, the data represent an extreme example of a lack of correlation between animal survival and haemopoietic parameters. Caution should be taken when applying endogenous colony counts as a means of screening potential anti-radiation drugs.     

The effect of 1,25-dihydroxyvitamin D3 on hematopoiesis in long-term human bone marrow cultures

The modulatory effect of 1,25-dihydroxyvitamin D3 (vit D) on the growth of myeloid progenitors and on the composition of the stromal layer in human bone marrow long-term cultures was studied. Vit D (2 X 10(-8) M) caused an enhancement in myeloid progenitor cell (CFU-C) growth in the nonadherent and adherent layers during the entire 5-week incubation period. The vitamin did not alter the differentiation pattern of CFU-C (monocyte-macrophage progenitors CFU-M, granulocytic progenitors CFU-G, or monocyte-granulocyte progenitors CFU-GM). Vit D caused a marked increase in the percentage of lipid-containing cells in the adherent layer and an increase in the number of cells that specifically bound My4 monoclonal antibody (McAb), that reacted positively to fluoride-sensitive alpha-naphthyl acetate esterase, and that phagocytosed Candida albicans (CA). Concentrated supernatants harvested from control cultures showed significant levels of myeloid colony stimulating factor (CSF) activity. The addition of vit D to cultures for 5 weeks did not alter CSF levels. These results suggest that vit D may play a role in hematopoiesis by acting directly on the progenitor cells or via the stromal cell production of stimulatory factor(s).     

A gene-controlling response of bone marrow progenitor cells to granulocyte-macrophage colony stimulating factors

The production of granulocytes and macrophages from progenitor cells in the bone marrow is controlled, in part, by a family of humoral regulators, termed colony stimulating factors (CSF). We have examined genetic factors controlling this process using in vitro cloning techniques. The inbred mouse strain LP/J showed elevated colony formation (CFU-C) in response to one subtype of CSF (G,M-CSF) compared to other strains of mice examined including the strain C57BL/6J. This variation resulted in a shift to the left of the CFU-C dose-response curve for LP/J. No difference between LP/J and C57BL/6J was seen with another subtype of CSF (CSF-1). Maximal CFU-C response was similar in the two mouse strains with both types of CSF, and mixing experiments with both types of CSF gave the same maximal level of colony formation as the individual CSF. (C57BL/6J X LP/J)F1 progeny exhibited a CFU-C dose-response curve to CSF-2 that was intermediate between the parental types, indicating additive inheritance. Genetic analysis of backcross progeny suggested that the variation in CFU-C response is probably determined by a single primary gene, although the variability of the colony formation assay has complicated interpretation of genetic studies. These results suggest that CSF-1 and G,M-CSF act independently on a single bone marrow progenitor cell population. The properties of the genetic variation for G,M-CSF response are consistent with an alteration in cellular receptors for G,M-CSF.     

人骨髓细胞培养液中干细胞刺激物的分析研究

人骨髓细胞体外培养液中含有高活力的 CSF,在长期培养过程中,CSF 活力的变化,与 CFU-C 数量的变化有大致平行的趋势。这种 CSF 对狗和小鼠也同样有效。人骨體条件液中的 CSF 对培养中的 CFU-S 也有明显的激发作用。这一结论可以从几个方面获得证据:第一,小鼠骨髓细胞与人骨髓条件液保温六小时后,再测定其中 CFU-S 数,结果是增加了。第二,经亚致死剂量照射的小鼠,腹腔注射适量的人骨髓条件液,其内源性脾结节也明显增多。第三,采用阿糖胞苷自杀的方法,测定小鼠骨髓经与人骨髓条件液保温后,其中 CFU-S 的自杀率也有增高的趋势。上述几方面的实验,说明人骨髓长期培养中存在着某种活性物质,调节体外造血。至于这种物质的来源,以及在体外造血中所起的作用,还需要做很多工作,逐步予以澄清。     

Formation of eosinophilic-like granulocytic colonies by mouse bone marrow cells in vitro

Formation of granulocytic and macrophage colonies in agar cultures of mouse marrow or spleen cells was stimulated by the addition of medium from pokeweed mitogen-stimulated cultures of mouse spleen cells (PKW-CM). Approximately 5% of the colonies developing were large, dispersed granulocytic colonies (DG-colonies) composed of cells with eosinophilic cytoplasmic granules. The capacity to stimulate DG-colonies was shown by media conditioned by PKW-treated lymphoid and peritoneal cells but not by other cells or organ fragments. Velocity sedimentation studies indicated that cells generating DG-colonies were separable from cells generating regular granulocytic or macrophage colonies. DG-colonies did not survive if transfered to cultures containing other forms of CSF. The active colony stimulating factor in pokeweed mitogen-conditioned medium which stimulates DG-colony formation was antigenically distinct from the factor stimulating granulocytic and macrophage colony formation, was separable electrophoretically from the latter factor and on gel filtration had an apparent molecular weight of 50,000. Although the cells in DG-colonies have not been established to be eosinophils, DG-colonies represent an interesting new system for analysing further aspects of the control of growth and differentiation in hemopoietic populations.     

Organ interactions in the regulation of hematopoiesis: in vitro interactions of bone, thymus, and spleen with bone marrow stem cells in normal, Sl/Sld and W/Wv mice.

Hematopoietic cell differentiation is influenced by organ-dependent microenvironmental factors as well as humoral regulators. A technique is described for examining certain aspects of the hemopoietic inductive microenvironment in vitro. Suspension and agar cultures of mouse bone marrow were used to study the effects of organ stromal factors on cellular proliferation and differentiation. Bone, spleen, and thymus fragments from irradiated mice were placed in direct contact with or separated by a Nuclepore membrane from syngeneic marrow cells growing in suspension cultures. Normal adult mouse bone and spleen influenced granulocytic differentiation as well as cell proliferation. In this system, bone marrow and organ fragments from W/Wv and SlSld mice behaved like those of their non-anemic littermates. The most prominent difference between W/Wv and Sl/Sla mice and their normal counterparts was observed in the inductionof CFU-C from splenic precursors un-er the influence of CSA. In both types of anemic mice, in vitro generation of CFU-C from spleen was abnormal in young animals but was corrected by four months of age.     

Effects of 10-day long exposure to gamma irradiation at low doses on bone marrow cells in mice

Effects of ten day long exposure to gamma-irradiation at low doses (mean dose rate of 1.5-2.0 m Gy/day, total dose of 15 m Gy) on hemopoietic (CFU-S) and stromal (CFU-F) progenitor cells from murine bone marrow were examined. The CFU-F content measured as in vitro fibroblastic colony number showed 1.5-4.5-fold increase. Additionally, the size of ectopic marrow transplants evaluated by counting myelokariocytes and CFU-S numbers also increased. No significant changes of CFU-S proliferation rate were found.     

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.