Characteristics of proliferation and differentiation of spleen colony-forming cells from bone marrow

By using c-band staining or sex chromosome identification techniques, we have demonstrated that some of the spleen colony-forming cells from normal bone marrow have the potential to form both myeloid and lymphoid elements.     

Effect of haemopoietic stem-cell proliferation regulators on early and late spleen colony-forming cells

An inhibitor and stimulator of CFU-s proliferation can be obtained from haemopoietic tissue containing, respectively, relatively quiescent CFU-s (e.g. normal bone marrow) and proliferating CFU-s (e.g. regenerating bone marrow). Their effects on the proliferative behaviour of steady-state and regenerating marrow CFU-s, which produce colonies 7, 10 and 12 days post-transplantation have been investigated. The results demonstrate changing sensitivities of CFU-s to inhibitor and stimulator as they progress through a developmental age structure, 'Older' CFU-s (producing early spleen colonies) are more sensitive to stimulator, 'Younger' CFU-s (producing late spleen colonies) are more sensitive to inhibitor.     

Stimulator of proliferation of spleen colony-forming cells in acute sterile inflammation

The presence and activity of a spleen colony-forming cell (CFU-S) proliferation stimulator was investigated in rat bone marrow after induction of sterile inflammation. Wistar rats were treated intraperitoneally with two 15 ml injections of 3.5% polyvinylpyrrolidone (PVP) at 18 h intervals, and the presence of CFU-S proliferation stimulator determined in bone marrow 6, 20 and 24 h after the first injection. The marrow of these mice was used to condition medium which was then fractionated using Amicon Diaflo ultrafiltration membranes. The 30–50 kDa fraction, taken from 20 h post-PVP-bone marrow extract, was found to induce cycling of d8-CFU-S in normal mouse bone marrow. This activity was not related to the presence of interleukins-1, -2 or -6 like activities in the material tested. The results demonstrate the existence of CFU-S proliferation stimulator in the bone marrow of rats with sterile inflammation (i.e. in an in vivo tissue response to non-specific cell stimulation), similar to that originally described as a macrophage product in mouse bone marrow after treatment with a variety of cytotoxic agents.     

The production of factors regulating the proliferation of haemopoietic spleen colony-forming cells by bone marrow macrophages

Media conditioned by normal murine bone marrow cells contain an inhibitor of haemopoietic spleen colony-forming cell proliferation that is concentrated in a nominal 50-100K fraction. Media conditioned by regenerating marrow cells contain a proliferation-stimulatory activity that is concentrated in a nominal 30-50K fraction. Cell separation experiments demonstrated that the activities are produced by adherent, phagocytic, radioresistant, Thy 1.2- Fc+, F4/80+ cells. Cultured macrophages, obtained from long-term marrow cultures or derived from progenitor cells in methyl cellulose cultures are also capable of producing inhibitory and stimulatory activities. The results are consistent with macrophages being an important source of stem cell proliferation regulators in the bone marrow.     

The production of factors regulating the proliferation of haemopoietic spleen colony-forming cells by bone marrow macrophages

Abstract. Media conditioned by normal murine bone marrow cells contain an inhibitor of haemopoietic spleen colony-forming cell proliferation that is concentrated in a nominal 50-100K fraction. Media conditioned by regenerating marrow cells contain a proliferation-stimulatory activity that is concentrated in a nominal 30-50K fraction. Cell separation experiments demonstrated that the activities are produced by adherent, phagocytic, radioresistant, Thy 1.2^- Fc⁺, F4/80⁺ cells. Cultured macrophages, obtained from long-term marrow cultures or derived from progenitor cells in methyl cellulose cultures are also capable of producing inhibitory and stimulatory activities. The results are consistent with macrophages being an important source of stem cell proliferation regulators in the bone marrow.     

The sensitivity of G0-state haemopoietic spleen colony-forming cells to a stimulus for proliferation

Haemopoietic spleen colony-forming units (CFU-s) close to the axis (axial CFU-s) of the long bones have a high probability of self-renewal. They are pluripotent cells and are largely in a G0-State. By contrast, CFU-s close to the bone surface (marginal CFU-s) have a lower probability of self-renewal and are probably more mature, though still pluripotent. Most CFU-s proliferation arises in this zone. As a consequence, marginal CFU-s tend to have shorter G0 histories than do axial CFU-s. Femoral marrow was, therefore, divided into axial and marginal populations and the sensitivity of the CFU-s to an endogenous CFU-s-specific proliferation-stimulating factor was assessed and compared by the tritiated thymidine suicide technique. It was found that axial CFU-s are considerably more resistant to stimulation than are marginal CFU-s in that larger doses for longer periods of exposure are required to increase the proliferative activity of the cells. This behaviour is consistent with the suggestion that cells with a low division probability exist in deeper levels of the quiescent G0-state. Although this hypothesis was developed from the behaviour of cells maintained in culture under sub-optimal physiological conditions, this phenomenon appears, in vivo, to be a characteristic of the stem cell population of haemopoietic tissue; their high resistance to stimulation maintaining the axial CFU-s in a quiescent state.     

The effect of erythropoietin on the growth and development of spleen colony-forming cells

The progressive growth and development of spleen colonies was studied in heavily irradiated host mice in which erythropoiesis was modified by various procedures. Erythropoietic activity in non-polycythemic hosts bearing spleen colonies was not increased by injections of exogenous erythropoietin. Detectable levels of erythropoietin were found in the heavily irradiated host mice suggesting that the failure of exogenous erythropoietin to modify erythropoiesis was because the host mice were already maximally stimulated by the high endogenous erythropoietin levels. Spleen colonies do not become erythroid in polycythemic mice. The injection of exogenous erythropoietin into heavily irradiated polycythemic hosts did not decrease the total number of spleen colonies produced by a given bone marrow transplant, as would be expected if erythropoietin acted directly on the colony-forming cells. Comparison of growth curves for colony-forming cells in the spleens of polycythemic hosts either receiving or not receiving erythropoietin indicated that the overall doubling time of colony-forming cells during the first ten days after transplantation was not changed by the daily injection of erythropoietin. These experiments are consistent with the concept that erythropoietin is necessary for the development of erythroid colonies. Erythropoietin acts upon some progeny of the colony-forming cell rather than the colony-forming cell itself.     

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.     

Stimulator of proliferation of spleen colony-forming cells in T-cell deprived mice treated with cyclophosphamide or irradiation

A role for T-cells in the regulation of CFU-S proliferation was investigated by determining the presence and activity of CFU-S proliferation stimulator (CFU-S stimulator) in adult mouse bone marrow after irradiation or cyclophosphamide (Cy) treatment. CBA mice previously deprived of T-cells by thymectomy, irradiation and bone marrow reconstitution (TIR) were thereafter treated with 4.5 Gy irradiation or 200 mg/kg Cy. Regenerating bone marrow cells of TIR and corresponding control mice after irradiation or Cy treatment produced CFU-S stimulator. The dose dependent increase in cytosine arabinoside cell death of normal bone marrow day 8 CFU-S was found when both CFU-S stimulators obtained after irradiation of TIR or corresponding control animals were tested. CFU-S stimulator activity in the bone marrow of TIR-Cy treated mice was also detected, but the effect was not dose-dependent. This was not related to the presence of an inhibitor of CFU-S proliferation. It appears that the CFU-S stimulator activity is not related to IL-6, IL-1 or IL-2, or to an inhibitor of IL-6 or IL-1 activity. The results demonstrate the existence of CFU-S proliferation stimulator unrelated to the two major monokines in the bone marrow of immunosuppressed mice.     

In vivo studies on the regeneration kinetics of enriched populations of haemopoietic spleen colony-forming cells from normal bone marrow

Functional properties of mouse haemopoietic spleen colony-forming cells, enriched 40- to 80-fold, from normal bone marrow were studied. It was found that: (1) the number of partially purified CFU-s (colony forming unit-spleen) required to rescue lethally irradiated mice was similar to the number of normal unfractionated bone marrow CFU-s giving the same level of protection; (2) the homing of partially purified CFU-s was similar to that of CFU-s from unfractionated bone marrow; (3) the regeneration of CFU-s in spleen was similar for enriched and unfractionated cell populations between 4 and 11 days after transplantation. In contrast, the rate of regeneration of CFU-s in femur was slower with enriched progenitor cells than with unfractionated bone marrow. The growth rate in femur, however, could be restored to normal by injecting freshly isolated syngeneic thymocytes with the enriched CFU-s population. The results indicate that the partially purified CFU-s are by themselves functionally normal and show that the rate of CFU-s repopulation in bone marrow can be affected by cell types other than spleen colony-forming cells.     

Haemopoietic stem cells: spleen colony-forming cells are normally actively proliferating

Abstract. The haemopoietic stem cells forming spleen colonies (CFU-S) had on average 30 to 40% of cells engaged in the DNA synthesis in normal mice continuously over 4 years. A majority of experiments aimed at the suppression of the CFU-S proliferation, which included suppression of the T-lymphocytes by means of cyclosporin A or by adult thymectomy, administration of antibacterial and antifungal agents and maintainance of mice in a sterile environment, suppression of antibody-producing cells by a successive administration of the bacterial lipopolysaccharide and cyclophosphamide and attempts to increase the total number of CFU-S in the body through massive transfusions of bone marrow cells or by grafting plugs of the bone marrow under the kidney capsulae, have not been sufficiently effective. A transient suppression of CFU-S proliferation occurred during recovery of the haemopoietic tissue from damage caused by cyclophosphamide. The results support the view that changes in CFU-S numbers and in the proportion of them in DNA synthesis may be positively correlated when CFU-S numbers fluctuate physiologically about their normal values. The failure to manipulate the CFU-S proliferation rate easily suggests that proliferation of these cells may not be under a strong 'switch on - switch off' control.     

Haemopoietic stem cells: spleen colony-forming cells are normally actively proliferating

The haemopoietic stem cells forming spleen colonies (CFU-S) had on average 30 to 40% of cells engaged in the DNA synthesis in normal mice continuously over 4 years. A majority of experiments aimed at the suppression of the CFU-S proliferation, which included suppression of the T-lymphocytes by means of cyclosporin A or by adult thymectomy, administration of antibacterial and antifungal agents and maintainance of mice in a sterile environment, suppression of antibody-producing cells by a successive administration of the bacterial lipopolysaccharide and cyclophosphamide and attempts to increase the total number of CFU-S in the body through massive transfusions of bone marrow cells or by grafting plugs of the bone marrow under the kidney capsulae, have not been sufficiently effective. A transient suppression of CFU-S proliferation occurred during recovery of the haemopoietic tissue from damage caused by cyclophosphamide. The results support the view that changes in CFU-S numbers and in the proportion of them in DNA synthesis may be positively correlated when CFU-S numbers fluctuate physiologically about their normal values. The failure to manipulate the CFU-S proliferation rate easily suggests that proliferation of these cells may not be under a strong 'switch on - switch off' control.     

Proliferative and differentiation potentials of skeletogenic bone marrow colony-forming cells

The clonal nature of bone marrow fibroblast colonies derived from clonogenic bone marrow osteogenic cells (CFUf) was proved by the chromosome analysis. During subsequent passages of multi-colony derived bone marrow fibroblast strains there occurs a pronounced increase in the cell number and in the number of osteogenic units (tested by transplantation in diffusion chambers). Single colony-derived strains are capable of forming bone and cartilage simultaneously. It follows that CFUf or part of them are clonogenic cells with high proliferative potentials and are common precursors for bone and cartilage tissue. Thus, CFUf may be regarded as osteogenic stem cells.     

Effect of the dose of injected hematopoietic cells on the number of daughter splenic colony-forming cells in spleen colonies

The number of daughter CFU-S per spleen colony was critically dependent on the injected cell dose and the time of registration. The influence of these factors on the measurement of self-maintenance CFU-S ability is discussed.     

Effect of bone marrow cells on colony-forming stromal cells in guinea pigs and on the proliferation of their cultured descendents

In the presence of irradiated bone marrow cells the efficiency of stromal colony formation increases from 0.8 +/- 0.2 to 3.6 +/- 0.4 per 10(4) explanted bone marrow cells. The growth-stimulating activity of bone marrow cells on passaged bone marrow fibroblasts depends on growth conditions of passages to which irradiated bone marrow cells are added. The response of proliferating bone marrow fibroblasts to stimulating activity of bone marrow cells is low, while addition of bone marrow cells to fibroblast cultures stimulates their proliferation.     

A cytological study of the capacity for differentiation of normal hemopoietic colony-forming cells

A two-stage procedure has been used to obtain hemopoietic spleen colonies derived from single precursor cells containing radiation-induced chromosomal markers. Of a total of 46 colonies examined, 17 were found to contain cells with abnormal karyotypes. In each of the 17 marked colonies, 90% or more of the dividing cells in the colony carried the same marker. Cell suspensions prepared from each of the individual colonies were tested for their content of dividing cells possessing recognizable differentiated functions. Metaphase cells with peroxidase-positive granules in their cytoplasm were considered to be members of the granulopoietic series, while metaphase cells which contained Fe⁵⁵ were considered to be members of the erythropoietic series. Results were obtained for 12 of the marked colonies, and in nine of these, the percentage of metaphases lacking the marker was less than the percentage of metaphases which were scored as erythropoietic, and also was less than the percentage of metaphases scored as granulopoietic. This is the result which would be expected if the marker were present in both erythropoietic and granulopoietic cells. These results provide support for the view that colony forming hemopoietic stem cells are multipotent, and that differentiation along more than one pathway can occur during the formation of macroscopic splenic colonies.