Dual activity of CSF-1, produced by a murine hybrid cell line and from other sources, on the growth of bone marrow stromal cells in culture.

Medium conditioned by the cell line A.4.10 was shown to produce a factor that inhibits the growth of bone marrow (BM) stromal foci in liquid cultures. In this study we demonstrated that CSF-1, present in this conditioned medium (CM), was largely responsible for this inhibition. This was concluded from the following findings: 1) the CSF-1 activity in the CM copurified with the inhibitory activity in several biochemical purification procedures; 2) an antibody against murine CSF-1 was able to neutralize the CSF-1 activity as well as the inhibitory activity in the A.4.10 CM; and 3) immunopurified murine CSF-1 from A.4.10 CM and from another murine source and recombinant human (rh) CSF-1 were all able to inhibit stromal cell growth. In secondary stromal cultures, inhibition was demonstrated at high cell densities but not at low densities, suggesting that accessory cells may be involved in the effect. When the dose rh CSF-1 was reduced to half of that required to produce 50% inhibition, stimulation of primary stromal foci growth was demonstrated, supporting observations by others that CSF-1 can act as a growth factor for BM stromal cells. In this report we thus demonstrate both inhibitory and stimulatory effects of CSF-1 on the growth of BM stromal cells in vitro.

Interaction between a murine myeloma cell line and bone marrow stromal cells.

Intravenous transplantation of an in vitro maintained murine myeloma cell line, 5T33, results in progressive growth in the bone marrow of C57Bl/KaLwRiJ mice. Concurrent with the growth of the tumor in vivo, the bone marrow stromal cells are inhibited, as assayed by their ability to form stromal cell foci and long-term monolayers in vitro. Inhibition of normal mouse marrow stromal cell growth also occurs when 5T33 cells are added to the marrow cells in vitro, and contact between the marrow and 5T33 cells is not necessary to achieve inhibition, indicating secretion of one or more diffusible inhibitory factors.

The resolution, enrichment, and organization of normal bone marrow high proliferative potential colony-forming cell subsets on the basis of rhodamine-123 fluorescence.

Cell sorting on the basis of rhodamine-123 (Rh123) fluorescence has been used in conjunction with negative immunomagnetic selection to analyze the high proliferative potential colony-forming cell (HPP-CFC) compartment of normal murine bone marrow and to resolve and enrich HPP-CFC subpopulations responsive to different combinations of the hemopoietic growth factors interleukin 1 alpha (IL-1 alpha), interleukin-3 (IL-3), and colony-stimulating factor 1 (CSF-1). HPP-CFC with a specific requirement for IL-1 alpha plus IL-3 plus CSF-1 in order to proliferate were resolved and enriched on the basis of their low Rh123 retention (Rh-dull), whereas HPP-CFC that grew in the presence of IL-3 plus CSF-1, IL-3 alone, or CSF-1 alone were Rh-bright. Further addition of IL-1 alpha to IL-3 plus CSF-1 stimulated few additional HPP-CFC in the Rh-bright fraction. Our data confirm the value of Rh123 as a probe for the dissection and analysis of the primitive hemopoietic stem cell (PHSC) compartment. These data also show that the Rh123 staining characteristics of IL-1 alpha plus IL-3 plus CSF-1-responsive HPP-CFC are consistent with the hypothesis that these HPP-CFC are closely related to PHSC with long-term reconstituting capacity in vivo and that they are among the most primitive progenitors yet detected in clonal agar culture.

An improved negative immunomagnetic selection strategy for the purification of primitive hemopoietic cells from normal bone marrow.

An improved negative immunomagnetic selection strategy has been devised for the enrichment of primitive hemopoietic cells using the high proliferative potential colony-forming cell (HPP-CFC) assay as an index of stem cell purification. Immunomagnetic selection was carried out using goat anti-rat conjugated M-450 Dynabeads and a cocktail of rat monoclonal antibodies directed against lineage antigens expressed on B-lymphocytes (B220), neutrophils and activated macrophages (7/4), differentiating erythroid cells (YW 25.12.7), and T-lymphocyte subsets (Lyt-2 and L3T4). This negative selection strategy results in the highly reproducible enrichment of HPP-CFC with negligible loss of HPP-CFC at the immunomagnetic selection step. A 30-fold enrichment of HPP-CFC stimulated by interleukin 3 (IL-3) plus colony-stimulating factor (CSF-1), or interleukin 1 alpha (IL-1 alpha) plus IL-3 plus CSF-1, is obtained with simultaneous resolution of HPP-CFC from progenitor cells of low proliferative potential responsive to CSF-1 alone (LPP-CFC). Flow cytometric analysis of these lineage-negative cells reveals that they almost exclusively exhibit the light-scattering characteristics of blast cells and the morphology of a candidate hemopoietic stem cell. Positive fluorescence-activated cell sorting of immunomagnetically pre-enriched normal bone marrow cells using wheat germ agglutinin yields cell preparations with a cloning efficiency of up to 45% and a HPP-CFC content of 20%.

Antagonism of the inhibitory effects of transforming growth factor-beta on colony formation of mouse bone marrow cells in vitro by increasing concentrations of growth factors.

Low concentrations of TGF-beta inhibited the clonal proliferation of three different preparations of mouse bone marrow progenitor cells in vitro. Normal marrow cells responsive to CSF-1; two-day post-fluorouracil cells responsive to CSF-1 plus IL-3 and IL-1 alpha; and regenerating seven-day post-fluorouracil cells responsive to CSF-1 plus IL-3, IL-1 alpha and IL-6 were all severely inhibited by TGF-beta 1; and the inhibitory effects were antagonized by increasing the concentrations of the relevant growth factors.

Progenitor cells in murine bone marrow stimulated by growth factors produced by the AF1-19T rat cell line.

The AF1-19T rat cell line has been found to produce an activity that acts synergistically with colony-stimulating factor 1 (CSF-1) to stimulate primitive high proliferative potential colony-forming cells (HPP-CFC) in mouse bone marrow (BM) that appear to be the same as those stimulated by the combination of 5637-cell-conditioned medium (CM) plus CSF-1 or recombinant human (rh) interleukin 1 (IL-1) plus recombinant murine (rm) interleukin 3 (IL-3) plus CSF-1. AF1-19T also produced granulocyte-macrophage colony-stimulating factor (GM-CSF), which could be separated from this synergistic activity by gel filtration followed by hydroxylapatite chromatography. Results obtained from the mouse thymocyte costimulation assay for IL-1, the hybridoma growth factor assay for interleukin 6 (IL-6), the ability to stimulate HPP-CFC, and the ability to block this stimulation with an antibody to murine IL-1 alpha suggest that the synergistic activity in AF1-19T-CM is probably a mixture of IL-1 activity and IL-6 or an IL-6-like activity. Other workers have described a progenitor cell population in mouse BM (CFU-A) that forms large colonies in response to AF1-19T-CM plus CSF-1 or GM-CSF plus CSF-1. Experiments involving the kinetics of recovery after 5-fluorouracil treatment and generation of progenitors suggest that the GM-CSF-plus-CSF-1-responsive progenitors, and hence CFU-A, are a more mature cell type than the more primitive HPP-CFC, responsive to 5637-cell-CM plus CSF-1 or rhIL-1 plus rmIL-3 plus CSF-1.

High proliferative potential colony forming cells.

High proliferative potential colony forming cells (HPP-CFC) in mouse bone marrow (BM) were defined functionally by their ability to form large colonies, greater than 0.5 mm diameter, and containing an average of 5 × 10(4) cells, in low-cell-density nutrient agar cultures after 10-14 d of incubation (1).

In vivo effects of interleukin-1 alpha on regenerating mouse bone marrow myeloid colony-forming cells after treatment with 5-fluorouracil.

Injection of a single dose of recombinant human interleukin-1 alpha (r-hu-IL-1 alpha) into mice 24 hr after 5-fluorouracil (FU) treatment resulted in an increased rate of recovery of three types of colony-forming cells (CFCs) in the bone marrow. Myeloid progenitors with high proliferative potential (responsive to CSF-1 + IL-3 + IL-1 alpha), low proliferative potential (responsive to CSF-1), megakaryocyte progenitors, and total nucleated cells per femur increased up to 5-fold, 7-fold, 3-fold, and 3-fold, respectively, in a dose related fashion compared with the control FU treated marrows. The kinetics of FU kill and recovery of these CFCs are shown.

Changes in cell surface antigen expression during murine bone marrow cell regeneration in vivo and proliferation in vitro.

Modulations in surface antigen expression during marrow regeneration in vivo, and proliferation in vitro in response to haemopoietic growth factors, were studied using a panel of monoclonal antibodies recognizing antigenic determinants expressed by primitive multipotential progenitor cells (Thy-1, Qa-m7), or lineage antigens restricted to committed progenitors and differentiated cells of the neutrophil/macrophage (7/4) and B lymphocyte (B220) lineages. These two categories of antigen exhibited differing responses to marrow perturbation and proliferation. Following administration of a cytotoxic dose of 5-fluorouracil, or lethal irradiation and transplantation of normal donor marrow, the levels of Thy-1 and Qa-m7 antigen expression rapidly increase, reaching a peak at the onset of regeneration: the nadir of marrow cellularity. Expression of these antigens returns to normal as regeneration proceeds and marrow is reconstituted. 7/4 and B220 antigen expression reflect the presence or absence of maturing cells bearing these markers: antigen expression declining following perturbation, and re-emerging during the course of regeneration. In vitro, when marrow cells taken from mice 8 days following treatment with 5-FU are grown in liquid culture in the presence of colony-stimulating factor-1 plus bladder cell carcinoma cell line 5637 conditioned medium, marrow cells are stimulated to proliferate and differentiate along the neutrophil/macrophage lineage. 7/4 antigen expression increases throughout the culture period, and B220 antigen is undetectable after the fifth day of culture. Thy-1 antigen expression also rises and remains elevated, and Qa-m7 antigen expression remains stable.

Interleukin 1 plus interleukin 3 plus colony-stimulating factor 1 are essential for clonal proliferation of primitive myeloid bone marrow cells.

The clonal growth in nutrient agar at low cell densities of high-proliferative potential colony-forming cells (HPP-CFC) of bone marrow obtained from mice treated 2 days earlier with 5-fluorouracil (FU) (FU2dBM) has been shown to require a combination of three growth factors, interleukin 1 (IL-1), interleukin 3 (IL-3), and macrophage colony-stimulating factor (CSF-1). These HPP-CFC have been enriched 140-fold from FU2dBM by fluorescence-activated cell sorting of 7/4-, B220-, and L3T4-negative cells. The mean of the plating efficiencies of these enriched populations was 4.4% and no growth was observed when the factors were used singly. Similarly, enrichments of 16-fold were obtained from FU2dBM using immunomagnetic Dynabeads with anti-7/4 plus anti-B220 (meaning plating efficiency 0.5%). The further additions of human granulocyte CSF or mouse granulocyte-macrophage CSF or both to IL-1 plus IL-3 plus CSF-1 did not increase HPP-CFC colony formation, but both augmented the small colony formation with IL-1 plus IL-3, IL-3 plus CSF-1, or IL-1 plus CSF-1.

The concentration and resolution of primitive hemopoietic cells from normal mouse bone marrow by negative selection using monoclonal antibodies and Dynabead monodisperse magnetic microspheres.

High proliferative potential colony-forming cells (HPP-CFC) detected in clonal agar culture in the presence of the combined stimulus of colony-stimulating factor 1 (CSF-1) + interleukin 3 (IL-3) + interleukin 1 alpha (IL-1 alpha) are closely related to developmentally early progenitor cells capable of reconstituting the hemopoietic system of lethally irradiated mice following transplantation. Flow cytometric analysis and sorting of normal, unperturbed bone marrow has shown that HPP-CFC are B220- and 7/4-, whereas the committed progenitors of the macrophage lineage responsive to CSF-1 alone (CSFCSF-1) are B220- and 7/4+. Negative immunomagnetic selection using an anti-7/4, anti-B220 antibody cocktail and second-antibody-coupled Dynabead microspheres to replace flow cytometry results in the highly reproducible and specific enrichment of HPP-CFC, and simultaneous resolution of HPP-CFC from CFCCSF-1. The tenfold enrichment of HPP-CFC compared with unfractionated bone marrow cell suspensions was comparable to that obtained by fluorescence-activated cell sorting. Enrichment was achieved with negligible loss of HPP-CFC at the immunomagnetic bead selection step, and 65% of HPP-CFC were recovered. The method is rapid, highly reproducible, and efficient, and has wide application to the separation of rare hemopoietic cells from normal bone marrow.

Transport and metabolism of 1-beta-D-arabinofuranosylcytosine in human ovarian adenocarcinoma cells.

1-beta-D-Arabinofuranosylcytosine (araC) is an effective drug in the i.p. therapy of ovarian carcinoma but little is known of its transport and metabolism in this tumor. Influx of araC at 1 microM into cultured human ovarian carcinoma cells (CI 80-13S) was largely inhibited by nanomolar concentrations of the nucleoside transport inhibitor, nitrobenzylthioinosine, while the residual influx (approximately 10%) was inhibited only by micromolar concentrations of nitrobenzylthioinosine. There was a two fold greater density of specific [3H]nitrobenzylthioinosine binding to the nucleoside transporters on the ovarian than on cultured human leukemic cells (RC2a). Calculated turnover rates of the nucleoside transporter for 1 microM araC were 5-fold less in ovarian than in leukemic cells. The major metabolic product of araC was 1-beta-D-arabinofuranosylcytosine 5'-triphosphate (araCTP) which accumulated in the ovarian cells to levels half those achieved in the leukemic cells. AraC was the major product of araCTP degradation in ovarian cells consistent with a pathway (araCTP--------araCMP----araC) which is different from that previously found in leukemic cells (araCTP--------araCMP----araUMP----araU). Despite these differences, ovarian carcinoma cells show substantial accumulation of araCTP from extracellular araC.

Multiparameter analysis of transplantable hemopoietic stem cells. II. Stem cells of long-term bone marrow-reconstituted recipients.

Marrow obtained from mice (referred to as [X + BM] mice) 3 months after gamma-irradiation (9 Gy) and bone marrow inoculation (0.1 femur equivalents) showed a reduced capacity to reconstitute hemopoiesis of irradiated mice and an increased sensitivity to 5-fluorouracil. Sorting of marrow from (X + BM) mice on the basis of low angle and 90 degrees scatter, and low rhodamine 123 fluorescence, showed that the set of cells that in normal mice is enriched for cells efficient at hemopoietic reconstitution manifested the greatest reduction in hemopoietic reconstituting ability. In spite of this reduction this fraction contained as many 13-day spleen colony-forming units (CFU-S13) and high proliferative potential colony-forming cells (HPP-CFC) as the equivalent fraction from normal littermate mice. This could be explained by postulating that neither CFU-S13 nor HPP-CFC are responsible for hemopoietic reconstitution, but that this is dependent on an earlier, pre-CFU-S13 cell. Alternatively only a subset of either CFU-S13 or HPP-CFC is responsible for long-term hemopoietic reconstitution after lethal irradiation. It would appear that at present there is no adequate method of predicting the hemopoietic reconstituting ability of a given marrow, other than to test it by injection into lethally irradiated hosts.

Generation of murine hematopoietic precursor cells from macrophage high-proliferative-potential colony-forming cells.

High-proliferative-potential colony-forming cells (HPP-CFC) have been described as primitive murine macrophage progenitors. We have previously demonstrated the existence of two populations of HPP-CFC: one population, termed HPP-CFC-1, is stimulated by the combination of macrophage colony-stimulating factor (CSF-1) plus haemopoietin-1 (H-1) and actively generates a second population of HPP-CFC, termed HPP-CFC-2. HPP-CFC-2 are stimulated by CSF-1 plus interleukin-3 and generate macrophage CFC that differentiate to form mature macrophages. In this study, we have demonstrated that HPP-CFC-1, when stimulated by CSF-1 plus H-1, generate colony-forming cells (CFC) for the megakaryocyte and granulocyte lineages in addition to HPP-CFC-2 and M-CFC. No CFC were detected with erythroid potential. In addition, HPP-CFC-1 generated cells that formed day-13 spleen colonies, cells that repopulated the bone marrow, cells with platelet-repopulating ability, and cells with erythroid-repopulating ability in lethally irradiated mice. These data support previous data that the HPP-CFC-1 represent a primitive hemopoietic cell population and demonstrate the multipotentiality but not totipotentiality of these cells.

A colorimetric liquid culture assay of a growth factor for primitive murine macrophage progenitor cells.

Synergistic factors from media conditioned (CM) by human placentas or the 5637 human bladder carcinoma cell line (SFH-HPCM and SFH-5637 respectively) have the ability to stimulate early progenitor cells in mouse bone marrow to form large colonies in agar cultures after 12-14 days, in the presence of CSF-1. Culture conditions have been examined and a quicker and more convenient liquid culture assay has been developed for this factor, using a tetrazolium salt to quantitate cell proliferation. The use of flat-bottomed vessels, high cell density, supra-optimal doses of CSF-1 or the addition of WEHI-3-CM to these cultures, all resulted in a decrease in the required incubation time. In combination, these modifications reduced the assay time to 4 days.

Detection of murine hemopoietin-1 in media conditioned by EMT6 cells.

We have previously reported replating experiments which demonstrated the existence of subpopulations of murine high-proliferative-potential colony-forming cells (HPP-CFC). One population of HPP-CFC, termed HPP-CFC-1, is stimulated by the combination of macrophage colony-stimulating factor (CSF-1) plus hemopoietin-1 (H-1), and actively generate a second population of HPP-CFC, termed HPP-CFC-2, which is responsive to CSF-1 plus interleukin-3 (IL-3). These reclonal experiments represent an assay system that discriminates between the two types of synergistic factors, namely H-1 and IL-3. To date H-1 has only been detected in medium conditioned by human cells. In this paper we have utilized these recloning experiments to study the synergistic factor(s) present in media conditioned by the murine mammary carcinoma cell line EMT6. Colony formation in secondary cultures containing cells picked up from primary cultures incubated in CSF-1 plus EMT6-conditioned medium was identical to that seen in secondary cultures containing cells picked up from primary cultures incubated in CSF-1 plus a source of H-1. Both sets of cultures demonstrated the generation of HPP-CFC-2 in the primary cultures, indicating the presence of a molecule in EMT6-conditioned medium that is the murine equivalent of H-1.

Increased Qa-m7 antigen expression is characteristic of primitive hemopoietic progenitors in regenerating marrow.

Developmentally early murine hemopoietic progenitor cells of high proliferative potential (HPP-CFC), which are detectable in clonal agar culture in the presence of the lineage-specific hemopoietic growth factor, colony-stimulating factor-1 (CSF-1) plus hemopoietin-1 (H-1), or interleukin 3 (IL 3), express relatively high levels of the Qa-m7 antigenic determinant. This determinant is progressively lost during differentiation, and the more committed progenitors which grow in the presence of CSF-1 alone are essentially devoid of Qa-m7. Significant increases in both the proportion of Qa-m7-positive myeloid cells and the level of Qa-m7 antigen expression have been observed in bone marrow cells regenerating after the administration of the cytotoxic agent 5-fluorouracil (5-FU). By exploiting this increase in Qa-m7 antigen expression during regeneration and the HPP-CFC-sparing properties of 5-FU, we have been able to enrich HPP-CFC from marrows 8 days post-5-FU treatment (FU8d) to purities of greater than 20%. Furthermore, discontinuous gradient centrifugation and fluorescence-activated cell sorting of FU8d bone marrow cells on the basis of their light-scattering properties and Qa-m7 expression has unmasked a further subset of HPP-CFC which strictly requires the combined stimulus of three hemopoietic growth factors (H-1, IL 3, and CSF-1) for clonal growth. These highly enriched subsets of HPP-CFC are either identical to or co-fractionate with transplantable multipotential hemopoietic progenitors capable of reconstituting the hemopoietic system of lethally irradiated mice. Up to one in three cells in these highly enriched fractions is an HPP-CFC, and up to one in two cells may be CFU-S assayed 13 days post-transplantation. In addition, these fractions contain progenitors capable of reconstituting the platelet, erythroid, and myeloid compartments of the marrow.

Subpopulations of mouse bone marrow high-proliferative-potential colony-forming cells.

Bone marrow cells taken from mice treated eight days previously with 5-fluorouracil, formed colonies consisting of 10-100 cells after four days of incubation in methylcellulose cultures containing only 500 cells/dish, in the presence of partially purified synergistic factor from human placental-conditioned medium (SFHPlac) and macrophage colony-stimulating factor (CSF-1). Replating of these colonies revealed a high incidence (27%) of another class of high-proliferative-potential colony-forming cells (HPP-CFC) responsive only to the synergistic factor in WEHI-3B-conditioned medium (SFW, which appears to be identical to interleukin 3) plus CSF-1. These colonies contained no HPP-CFC responsive to SFHPlac plus CSF-1, although primary cultures incubated for 14 days in the presence of SFHPlac plus CSF-1 formed large colonies (diameter greater than 0.5 mm), indicating the presence of HPP-CFC responsive to SFHPlac plus CSF-1 in the starting marrow. Primary cultures containing SFW alone, or purified interleukin 3 alone, also gave rise to colonies consisting of 10-100 cells after four days of incubation in methylcellulose cultures; however, the cells from these colonies were unable to form large colonies on replating in the presence of either CSF-1 plus SFHPlac or CSF-1 plus SFW. These results suggest that two distinct populations of HPP-CFC exist and that the population of HPP-CFC stimulated by CSF-1 plus SFHPlac differentiates to form HPP-CFC that respond to CSF-1 plus SFW.

Regulation of very primitive, multipotent, hemopoietic cells by hemopoietin-1.

Hemopoietin-1 (H-1) is known to act synergistically with CSF-1, a mononuclear phagocyte growth factor, to induce the development of primitive hemopoietic cells. To determine whether purified H-1 also acts on multipotent hemopoietic cells, its ability to act synergistically with interleukin-3 (IL-3) and erythropoietin (Epo) was tested in methyl cellulose cultures of murine bone marrow cells. In the presence of IL-3, H-1 increased the number of colonies formed by primitive, multipotent cells by approximately 30-fold. H-1 alone or H-1 plus Epo produced no colonies. Forty percent of the colonies induced by H-1 plus IL-3 contained cells that could be subcultured at least twice, whereas cells from colonies induced by IL-3 alone could not be similarly subcultured. Thus H-1 permits CSF-1 or IL-3 to act on cells more primitive than those acted on by either growth factor alone. The results indicate that H-1 acts on the most primitive hemopoietic cells yet shown to proliferate and differentiate in culture.