Comparison of in vitro and in vivo modulation of myelopoiesis by biological response modifiers

Summary In vitro growth and differentiation of granulocyte-macrophage progenitor cells (GM-CFU-C) requires colony-stimulating factors (CSF), and an in vivo role for CSF has also been proposed. Prostaglandins of the E series (PGE) have been reported to serve as negative feedback regulators of myelopoiesis. Here, we report evidence of augmented CSF secretion by mouse peritoneal Mo (macrophages) and bone marrow cells in vitro upon stimulation with various biological response modifiers (BRMs). Optimal induction of CSF secretion occurred after in vitro treatment of peritoneal Mo and mononuclear bone marrow cells with 50 g/ml poly ICLC (polyriboinosinic-polycytidylic acid poly-L-lysine), 5 g/ml lipopolysaccharide (LPS), or 500 U/ml interferon (IFN_,) for 2 days. The in vitro stimulation of CSF secretion was paralleled by an increase in PGE secretion by Mo and bone marrow cells. The PGE secretion could, however, be selectively blocked by preincubating the cells for 3 h with indomethacin (10^–7 Mol) leaving CFS production intact. In vivo treatment of mice with either maleic anhydride divinyl ether copolymer (MVE-2; 25 mg/kg) or poly ICLC (2 mg/kg) significantly increased levels of CSF in serum, as well as in culture supernatants of in vivo-treated peritoneal Mo and bone marrow cells. The increase in serum CSF levels and in secretion of CSF by peritoneal Mo and bone marrow cells was followed by a dose-dependent increase in GM-CFU-C, in nucleated bone marrow cells, and in peripheral blood leukocytes. The same BRMs also stimulated the secretion of PGE by in vivo-activated peritoneal Mo, but not by bone marrow cells. Pretreatment of the mice with indomethacin (4 mg/kg) almost completely suppressed PGE secretion by peritoneal Mo, but did not change the CSF secretion by peritoneal Mo or bone marrow cells and had no significant effect on bone marrow cellularity. Therefore, MVE-2 and poly ICLC, in addition to their immunomodulatory activity, can also have stimulatory effects on myelopoiesis, presumably mediated through secretion of CSFs. Protection and/or restoration of bone marrow function could thus either provide the opportunity for more extensive chemotherapy or could increase the number of Mo effector cells available for activation against tumor targets.     

Growth factors that stimulate human granulocyte—macrophage colony formation produced by the cell line CM-S

CM-S is an autonomous cell line of human hemopoietic precursor cells inducible to monocyte-macrophage differentiation in response to appropriate inducing agents. CM-S cells produce factors that stimulate their own growth and proliferation, and are also capable of stimulating clonal proliferation of human, but not mouse, monocytic and granulocytic bone marrow progenitor cells in viscous medium. Preliminary purification steps have demonstrated at least two species, one of which (MW 30,000–50,000) retains both these activities, while the other (MW ≤ 10,000) apparently retains only the autostimulatory activity. CM-S cells could thus be a useful source for the purification of human colony stimulating factors (CSFs). CM-S cells also respond to factors present in human placenta conditioned medium, known to contain human CSF. This suggests that CM-S cells could provide a homogeneous target cell population for testing CSFs from other human sources.     

Isolation of colony stimulating factor from human milk

Human milk contains colony stimulating factor (CSF), a polypeptide growth factor, which stimulates in in vitro bone marrow culture proliferation and differentiation of colony forming granulocytic macrophage progenitor cells (CFU-GM) to form colonies. This activity was not found in either bovine milk or colostrum when assayed in human or mouse bone marrow cells. The human milk CSF activity is destroyed by treatment with proteases. However, neither 6M urea, 4M guanidine hydrochloride, 5 mM dithiothreitol, nor exposure to pH 2 will inactivate the milk derived CSF. Gel filtration and isoelectric focusing indicate that human milk CSF differs biochemically from the other CSFs isolated from various sources and has a molecular weight between 250,000 and 240,000 and an isoelectric point between 4.4 and 4.9.     

Hierarchical down-modulation of hemopoietic growth factor receptors

Granulocytes and macrophages can be produced in vitro when progenitor cells from mouse bone marrow are stimulated by any of four distinct colony stimulating factors, Multi-CSF (IL-3), GM-CSF, G-CSF, and M-CSF (CSF-1). At 0 degrees C the four CSFs do not cross-compete for binding to bone marrow cells, indicating that each has a specific cell surface receptor. However, at 21 degrees C or 37 degrees C, Multi-CSF inhibits binding of the other three CSFs and GM-CSF inhibits binding of G-CSF and M-CSF. Rather than competing directly for receptor binding, the binding of Multi-CSF, GM-CSF, or G-CSF to their own receptor induces the down-modulation (and thus activation) of other CSF receptors at 37 degrees C. The pattern and potency of down-modulation activity exhibited by each type of CSF parallels the pattern and potency of its biological activity. We propose a model in which the biological interactions of the four CSFs are explained by their ability to down-modulate and activate lineage-specific receptors.     

The role of colony-stimulating factor in granulopoiesis

The proliferation and maturation of granulocytic-monocytic stem cells appears to be controlled by a series of closely related glycoproteins termed “colony-stimulating factors” (CSFs). Recently, we devised a 6-step scheme for the purification of murine fibroblast (L-cell)-derived CSF. Ten liter pools of conditioned media were concentrated by ultrafiltration, precipitated by ethanol, and separated on DEAE cellulose, Con-A Sepharose, and Sephadex G 150. The CSF was separated from trace contaminants, including endotoxin, by density gradient centrifugation. The purified material was radioiodinated and used to define the serum half-life and in vivo distribution. Following IV injection there was a biphasic serum clearance with a t½ of 24–40 min and 2–2½ hours in the first and second phases. Approximately 25% of the tracer was excreted in the urine at 6 h; however, urinary radioactivity was due to low molecular weight peptides. Simultaneous studies by radioimmunoassay showed a similar rapid serum clearance of unlabeled CSF but virtually no urinary CSF activity. Thus, assays for urinary CSF may not provide useful measures of in vivo CSF activity. Further in vitro studies have defined the interaction of CSF with responsive cells in the marrow. Varying doses of CSF were incubated with 10⁷ marrow cells for intervals of 24–48 h. The major increment in cell-associated radioactivity occurred between 6 and 16 h. The reaction was saturable with 1–2 ng/ml CSF. Binding was prevented by cold CSF, but not by other proteins. Irradiation yielded only a minimal reduction in CSF binding. The interaction of CSF with marrow cells appeared to require new protein synthesis, as binding was completely inhibited by cycloheximide and puromycin. Irradiated mice injected with antibodies to CSF showed an inhibition of granulopoiesis by marrow cells in peritoneal diffusion chambers; however, granulopoiesis in the intact bone marrow was unaffected. Granulpoiesis in long-term marrow cultures was also unaffected by anti-CSF. These different responses may be due to accelerated clearance of injected CSF in nonirradiated mice or to extensive stromal interactions that modulate and perhaps control granulocytic differentiation in the intact bone marrow microenvironment.     

Reproducible generation of autonomous malignant sublines from non-tumorogenic murine interleukin 3-dependent mast cell lines

Murine interleukin 3 (IL-3)-dependent permanent mast cell lines derived from normal mouse bone marrow were established using pokeweed mitogen-stimulated spleen cell conditioned medium (SCM) as a source of IL-3. When propagated continuously in media containing a high concentration of IL-3 (20% SCM or 20 U/ml murine recombinant IL-3 (rIL-3], all the cell lines remained strictly factor-dependent in vitro and non-tumorogenic in vivo. However, we were able to reproducibly generate autonomous sublines from cultures supplemented with low amounts of IL-3 (1% SCM or 2 U/ml rIL-3). Abrogation of exogeneous growth factor dependency was always associated with neoplastic transformation. In newly generated autonomous sublines an autocrine mechanism of growth regulation was evident in vitro.     

Properties of colony-stimulating factors produced by macrophage cell lines and hybrid cells

Colony-stimulating factors (CSFs) produced by two simian virus 40(SV40) transformed macrophage cell lines (BAM1 and BAM3), and three hybrids (HM3-11, HM3-12, and HM3-14) derived from fusion between BAM3 and a Chinese hamster cell line (hs222-16) were examined. HM3-11 and HM3-14 produce two molecular species of CSF, which are not found in the conditioned media from cultures of BAM1 and BAM3 or lipopolysaccharide (LPS), phorbolmyristate-acetate (PMA), and zymosan-stimulated BAM3. HM3-12, which is classified into another group in terms of CSF secretion, does not produce these two CSFs. On the basis of various criteria, one of these CSF species (peak 1-CSF) was characterized as a macrophage-colony-stimulating factor (M-CSF). The other CSF (peak 2-CSF) induced a group of bone marrow cells in granulocytes and macrophages as well as growth of a mast cell line, IC2. This CSF has an apparent molecular weight of 18,000, estimated by SDS-polyacrylamide gel electrophoresis. Unlike interleukin 3 (IL3) from WEHI-3 cells, the growth factor activity of peak 2-CSF binds to DEAE-Sephacel. Thus, peak 2-CSF is similar to a granulocyte-macrophage colony-stimulating factor (GM-CSF) rather than to IL3. The anti L cell CSF serum does not inhibit the CSF activity in Chinese hamster fibroblast conditioned medium, and the IC2 cells do not respond to Chinese hamster lung conditioned medium (CHLCM), suggesting that peak 1- and peak 2-CSF are of mouse origin.     

Systematic analysis of the ability of stromal cell lines derived from different murine adult tissues to support maintenance of hematopoietic stem cells in vitro.

Hematopoietic stem cells interact with a complex microenvironment both in vivo and in vitro. In association with this microenvironment, murine stem cells are maintained in vitro for several months. Fibroblast-like stromal cells appear to be important components of the microenvironment, since several laboratories have demonstrated that cloned stromal cell lines support hematopoiesis in vitro. The importance of the tissue of origin of such cell lines remains unknown, since systematic generation of stromal cell lines from adult tissues has never been accomplished. In addition, the capacity of stromal cell lines to support reconstituting stem cell has not been examined. We have previously described an efficient and rapid method for the immortalization of primary bone marrow stromal cell lines (Williams et al., Mol. Cell. Biol. 8:3864-3871, 1988) which can be used to systematically derive cell lines from multiple tissues of the adult mouse. Here we report the immortalization of primary murine lung, kidney, skin, and bone marrow stromal cells using a recombinant retrovirus vector (U19-5) containing the simian virus large T antigen (SV40 LT) and the neophosphotransferase gene. The interaction of these stromal cells with factor-dependent cells Patterson-Mix (FDCP-Mix), colony forming units-spleen (CFU-S), and reconstituting hematopoietic stem cells was studied in order to analyze the ability of such lines to support multipotent stem cells in vitro. These studies revealed that stromal cell lines from these diverse tissues were morphologically and phenotypically similar and that they quantitatively bound CFU-S and FDCP-Mix cells equally well. However, only those cell lines derived from bone marrow-supported maintenance of day 12 CFU-S in vitro. One lung-derived stromal cell line, ULU-3, supported the survival of day 8 CFU-S, but not the more primitive CFU-S12. A bone marrow-derived stromal cell line, U2, supported the survival of long-term reconstituting stem cells for up to 3 weeks in vitro as assayed by reconstitution 1 year post-transplant. These studies suggest that adherence of HSC to stromal cells is necessary but not sufficient for maintenance of these stem cell populations and that bone marrow provides specific signals relating to hematopoietic stem cell survival and proliferation.     

Induction of colony-stimulating factors by Plasmodium cynomolgi components

Plasmodium cynomolgi total parasite antigens soluble in culture medium (P.c.SA), when injected in monkeys (Macaca mulatta) intravenously, induced the synthesis and secretion of serum colony-stimulating factors (CSFs). In vitro cultured monkey splenic macrophages and blood monocytes, following incubation with P.c.SA, also elaborated CSFs: the splenic macrophages responded more. Peak CSFs levels, both in vivo and in vitro, were attained after 8 hours of P.c.SA stimulation, and thereafter declined to baseline values within 48 hours. CSFs, both in serum and in conditioned medium, induced the formation of macrophage, granulocyte and granulocyte-macrophage colonies in vitro, in the same proportion, indicating that committed progenitor cells responded to CSF from both sources in a similar way. Polymyxin B treatment had no effect on P.c.SA stimulated CSF elaboration by macrophages, suggesting an LPS-independent mechanism of CSF induction. CSF synthesis appeared to be de novo, as cycloheximide treatment of macrophages completely inhibited CSF production. These observations indicate that P. cynomolgi components can induce CSF synthesis.     

Radiosensitivity increases with differentiation status of murine hemopoietic progenitor cells selected using enriched marrow subpopulations and recombinant growth factors

The radiosensitivity of populations of colony-forming cells (CFC) in murine bone marrow was investigated using different recombinant colony-stimulating factors (CSFs; murine IL-3 and granulocyte-macrophage CSF and human granulocyte CSF), or purified murine macrophage CSF. With unfractionated normal bone marrow the CFC increased in radiosensitivity as they progressed through the granulocyte lineage. The D0 values ranged from 129 +/- 12 cGy for CFC stimulated with GM-CSF down to 42 +/- 2 cGy after stimulation with G-CSF. IL-3 stimulated a CFC population which gave the only survival curve with a shoulder (n = 1.9 +/- 0.3). With semipurified populations of primitive or bipotential CFC, D0 values were generally lower with respect to the equivalent values for unpurified bone marrow (range 62 +/- 7 cGy to 135 +/- 7 cGy). Changes in cluster/colony ratio and colony morphology together possibly with products of accessory cells influence the interpretation of the radiosensitivity parameters.     

Kinetics of the clonal proliferation of granulocytes and macrophages in cultures of mouse bone marrow cells as supported by two distinct types of colony-stimulating factors

Two different types of colony-stimulating factors (CSF) were used to support the clonal growth of myeloid progenitor cells (CFUc) in semi-solid agar or viscous methylcellulose cultures of mouse bone marrow cells. The cultures stimulated for 5 days with RSP-2-P3 cell CSF (CSFRSP) contained mainly granulocyte colonies, whereas the cultures stimulated for 10 days with human urine CSF (CSFhu) contained mainly monocyte/macrophage colonies. Four lines of study were carried out: 1) a kinetic study using combinations of the two types of CSFs in the same culture; 2) a study of transferring CFUc from the initial 3-day cultures to recipient cultures containing the same or different types of CSF; 3) an examination of the morphology over time of colonies that were confined by glass capillaries plunged in agar; and 4) electron microscopic observations on disintegrating granulocytes. The results of all these lines of study suggest that about one third of the CFUc can be stimulated both by CSFRSP and CSFhu while the other two thirds react specifically either with CSFRSP or with CSFhu. The present study also suggests that granulocytes in the culture stop proliferation and disintegrate while macrophages are still growing there. Thus, mixed-type colonies containing both macrophages and granulocytes later become macrophage colonies.     

Human macrophage colony-stimulating factor inhibits bone resorption by osteoclasts disaggregated from rat bone

Colony stimulating factors (CSFs) regulate the survival, proliferation and differentiation of haemopoietic progenitor cells, as well as the functional activity of mature cells. Because the osteoclast is derived from haemopoietic tissue, and because osteoblastic cells produce CSFs, we tested the effects of several CSFs on bone resorption by osteoclasts disaggregated from neonatal rat long bone. We found that recombinant macrophage (M)-CSF was a potent inhibitor of bone resorption, causing significant inhibition at concentrations similar to those required to support the growth of macrophage colonies in agar. Unlike other inhibitors of osteoclastic resorption, M-CSF did not alter cytoplasmic motility in time-lapse recordings, suggesting that M-CSF may inhibit osteoclasts through a different transduction mechanism. None of the remaining cytokines tested (granulocyte-macrophage CSF, interleukin 3, interleukin 6, or interferon γ) influenced bone resorption. M-CSF production may be a mechanism by which osteoblastic cells, which produce M-CSF, may regulate osteoclastic function. Alternatively, inhibition of osteoclastic resorption by a CSF that is responsible for amplification of the macrophage compartment may reflect a close lineage relationship between mononuclear phagocytes, in which M-CSF induces a diversion of lineage resources away from osteoclastic function.     

Purification and characterization of human granulocyte colony-stimulating factor (G-CSF).

A colony-stimulating factor (CSF) has been purified to homogeneity from the serum-free medium conditioned by one of the human CSF-producing tumor cell lines, CHU-2. The molecule was a hydrophobic glycoprotein (mol. wt 19,000, pI = 6.1 as asialo form) with possible O-linked glycosides. Amino acid sequence determination of the molecule gave a single NH2-terminal sequence which had no homology to the corresponding sequence of the other CSFs previously reported. The biological activity was apparently specific for a neutrophilic granulocyte-lineage of both human and mouse bone marrow cells with a specific activity of 2.7 X 10(8) colonies/10(5) non-adherent human bone marrow cells/mg protein. The purified CSF can be regarded as a G-CSF of human origin and will become a useful material for investigation of regulatory mechanisms of human granulopoiesis.     

Effects of colony-stimulating factors on cellular cytotoxicity

 Colony-stimulating factors (CSF) are used clinically in the treatment of chemotherapy-induced myelosuppression and in support of bone marrow transplantation. As CSF are known to have pleiotropic functions, their effects on cellular cytotoxicity were analysed in vitro against bladder carcinoma cell lines. By means of an L-[³H]methionine-release assay, the cytotoxicity of peripheral blood mononuclear cells against the natural-killer(NK)-cell-resistant bladder carcinoma cell lines BT-A and SBC-7 was measured using different effector/target-cell ratios. Costimulatory effects of granulocyte-colony-stimulating factor (G-CSF), granulocyte/macrophage-colony-stimulating factor (GM-CSF), interleukin-3 (IL-3) and stem cell factor (SCF) on the generation of lymphokine-activated killer (LAK), bacillus Calmette-Guérin-activated killer (BAK) and natural killer (NK) cell cytotoxicity were investigated in this assay. Furthermore, the effect of CSF on proliferation of urothelial tumor cells in vitro was determined by a [³H]thymidine DNA-labelling technique. GM-CSF, but not G-CSF, IL-3 or SCF, was able to increase NK, BAK and LAK cytotoxicity in a dose-dependent manner. No acceleration of carcinoma cell proliferation was evident under the conditions of our assay. These data indicate the costimulatory effect of GM-CSF on cellular cytotoxicity, which might be used for immunotherapeutic purposes. Received: 30 July 1996 / Accepted: 20 December 1996     

Recombinant human granulocyte-colony stimulating factor and recombinant human macrophage-colony stimulating factor synergize in vivo to enhance proliferation of granulocyte-macrophage, erythroid, and multipotential progenitor cells in mice

Combinations of low dosages of purified recombinant human (rh) macrophage-colony stimulating factor (M-CSF; also termed CSF-1) and rh granulocyte-colony stimulating factor (G-CSF) were compared alone and in combination for their influence on the cycling rates and numbers of bone marrow and splenic granulocyte-macrophage, erythroid, and multipotential progenitor cells in vivo in mice pretreated with iron-saturated human lactoferrin (LF). LF was used to enhance detection of the stimulating effects of exogenously added CSFs. Concentrations of each CSF that were not active in vivo when given alone were active when given together, with the other CSF. The concentrations of rhM-CSF and rhG-CSF needed to increase progenitor cell cycling in the marrow and spleen were reduced by factors of 40-200 when these CSFs were administered in combination with low dosages of the other CSF. At the concentrations of rhM-CSF and rhG-CSF tested, synergism was not noted on absolute numbers of progenitor cells or total nucleated cell counts per organ or circulating in the blood. These findings may have potential relevance when considered in a clinical setting where the CSFs might be used in combination with other biotherapy and/or chemotherapy.     

Development of rat anti-mouse interleukin 3 monoclonal antibodies which neutralize bioactivity in vitro

Several rat anti-mouse interleukin 3 (IL-3) monoclonal antibodies have been developed which inhibit the biologic activity of mouse IL-3. These antibodies were produced in rats immunized with preparations of purified, recombinant mouse IL-3, obtained from transiently transfected COS7 cell supernatant. Hybridomas secreting anti-IL-3 were selected initially either on the basis of their giving a positive signal in an indirect enzyme-linked immunosorbent assay, or for their ability to inhibit the proliferation of the IL-3-dependent mouse mast cell line, MC/9. Neutralizing rat monoclonal IgG1, IgG2a, and IgG2b antibodies have been identified; these also block IL-3-induced proliferation of the NFS-60 and IC2 cell lines. These antibodies also blocked the IL-3-induced proliferation of mouse bone marrow-derived colony-forming units-culture suggesting that the same epitopes on IL-3 influence receptor recognition for both the proliferation of factor-dependent cell lines as well as normal bone marrow cells. Fab fragments produced from certain of the IgG2a-neutralizing antibodies blocked as well as the parent IgG. Antibody cross-blocking studies identified one neutralizing antibody apparently recognizing an epitope that was spatially distinct from those recognized by the other blocking antibodies tested. The development of these neutralizing rat monoclonal antibodies to mouse IL-3 should facilitate further investigation on the role of this factor in hemopoietic regulation.     

Secretion of colony-stimulating factors by T cell clones. Role in adoptive protection against Listeria monocytogenes

CSF have been postulated to be important mediators of host defenses. The current studies were undertaken to investigate the production of CSF by Listeria-specific, T cell clones and to assess the participation of CSF in anti-listerial host resistance. Listeria-specific L3T4+, Lyt-2- T cell clones were isolated and expanded by standard techniques. The clones themselves protected mice from listerial challenge when injected intravenously, and supernatants generated from Ag-stimulated clones were protective. In order to define factors important in the protection, supernatants from the clones were assayed for CSF by several in vitro assays. Total colony-stimulating activity was measured with a bone marrow colony-forming assay. T cell clones secreted 1000 to 2000 U/ml of colony-stimulating activity after 48 hours of stimulation with specific antigen. The relative amounts of the various CSF were determined by the capacity of supernatants to support proliferation of the factor-dependent cell lines FDCP-1 and 32D cl 3 in the presence and absence of specific anti-CSF antibodies. Results showed that most of the CSF activity was due to granulocyte-macrophage (GM)-CSF and IL-3. The role of GM-CSF in anti-listerial host resistance was assessed in two types of experiments. In one set of experiments GM-CSF activity was neutralized in the supernatants by addition of specific rabbit anti-GM-CSF antibodies. Treated and untreated supernatants were then tested for their capacity to protect nonimmune mice against listerial challenge. Neutralization of GM-CSF in the supernatants decreased the protective capacity of the supernatants by approximately 23%. In a second set of studies, the administration of recombinant murine GM-CSF was shown to protect mice from challenges of L. monocytogenes. Taken together, these experiments provide evidence that CSF are important mediators of immune T cell mediated host defenses.     

Oncogene cooperation in lymphocyte transformation: malignant conversion of E mu-myc transgenic pre-B cells in vitro is enhanced by v-H-ras or v-raf but not v-abl.

Although transgenic mice bearing a c-myc gene controlled by the immunoglobulin heavy-chain enhancer (E mu) eventually develop B-lymphoid tumors, B-lineage cells from preneoplastic bone marrow express the transgene but do not grow autonomously or produce tumors in mice. To determine whether other oncogenes can cooperate with myc to transform B-lineage cells, we compared the in vitro growth and tumorigenicity of normal and E mu-myc bone marrow cells infected with retroviruses bearing the v-H-ras, v-raf, or v-abl oncogene. The v-H-ras and v-raf viruses both generated a rapid polyclonal expansion of E mu-myc pre-B bone marrow cells in liquid culture and 10- to 100-fold more pre-B lymphoid colonies than normal in soft agar. The infected transgenic cells were autonomous, cloned efficiently in agar, and grew as tumors in nude mice. While many pre-B cells from normal marrow could also be induced to proliferate by the v-raf virus, these cells required a stromal feeder layer, did not clone in agar, and were not malignant. Most normal cells stimulated to grow by v-H-ras also cloned poorly in agar, and only rare cells were tumorigenic. With the v-abl virus, no more cells were transformed from E mu-myc than normal marrow and the proportion of tumorigenic pre-B clones was not elevated. These results suggest that both v-H-ras and v-raf, but apparently not v-abl, collaborate with constitutive myc expression to promote autonomous proliferation and tumorigenicity of pre-B lymphoid cells.     

Extracellular calcium modulates proliferation of factor dependent hemopoietic cells

Blockade of the calcium channel inhibited, in a dose-dependent manner, the proliferation of the IL-3 dependent FDCP-1 cell line and normal murine bone marrow cells. Similar results were obtained by lowering the amount of extracellular calcium using specific chelators or a calcium-free medium. These results suggest that factor-dependent cell proliferation is highly sensitive to fluctuations in the concentration of extracellular calcium.