Hydrophobic adsorption chromatography of colony-stimulating activities and erythroid-enhancing activity from the human monocyte-like cell line, GCT

The human cell line, GCT, secretes hemopoietins into serum-free culture medium. The conditioned medium contains activities that stimulate neutrophil-monocyte, macrophage, eosinophil, and erythroid colony growth in human marrow cultures. We have used hydrophobic adsorption chromatography to separate a neutrophil-monocyte colony-stimulating factor (CSF) from the other colony-stimulating activities. This hydrophobic CSF has no eosinophil-stimulating activity and is virtually devoid of erythroid-stimulating activity.     

Human cell lines that elaborate colon-stimulating activity for the marrow cells of man and other species.

We have established two human cell lines which elaborate colony-stimulating activity (CSA) for at least four species: man, mouse, rabbit, and dog. One, GCT, was isolated from a lung metastasis of a fibrous histiocytoma; the other, RC4, from a monocyte-enriched fraction of normal blood. Medium conditioned by either GCT or RC4 cells was more potent in stimulating human marrow growth in vitro than was monocyte-conditioned medium or human leukocyte feeder layers. Fractionation of cell-line-conditioned medium by Sephacryl S-200 chromatography indicated that the maximum activity of the CSA for human marrow cells is eluted within the range of 30,000-40,000 daltons. These cells lines provide a continuous source of large quantities of conditioned medium for purification of CSA. Moreover, the invariable growth-supporting activity for all species tested and the high potency of cell-line CSA facilitates studies of its elaboration and biologic effects.     

Granulocyte macrophage colony-stimulating activity production by cultured human thymic nonlymphoid cells is regulated by endogenous interleukin-1

Supernatants of cultured human thymic nonlymphoid cells were assayed for granulopoietic factors using cultures of low density bone marrow mononuclear cells (LD-BMMC). Thymic nonlymphoid cell-conditioned medium (TNLC-CM) supported vigorous myeloid colony growth of LD-BMMC, and of LD-BMMC depleted of T lymphocytes and/or monocytes. Colony stimulating activity (CSA) in TNLC-CM was abrogated by a highly specific neutralizing antiserum against recombinant human granulocyte-macrophage colony-stimulating factor (GM-CSF). TNLC-CM also enhanced colony growth in LD-BMMC stimulated by colony stimulating activity from a giant cell tumor culture (GCT). The enhancing activity of TNLC-CM, unlike its CSA activity, required the presence of adherent cells in the marrow cell culture. The addition of anti-interleukin-1 (anti-IL-1) antibody to TNLC-CM inhibited the GCT-enhancing activity, but not the CSA. When the anti-IL-1 immunoglobulin was added directly to cultures of thymic nonlymphoid cells, GM-CSF production was completely inhibited, and the GCT enhancing activity was neutralized. We conclude that an intercellular regulatory network exists in cultured thymic explants in which GM-CSF expression is induced by IL-1. In this system, the granulopoietic effect of IL-1 derives not from a direct effect on myeloid progenitors, but from its ability to recruit CSA production by other cells.     

Stromal growth factor production in irradiated lectin exposed long-term murine bone marrow cultures

Hematopoietic regulatory factors produced by adherent (stromal) cells in long-term murine bone marrow cultures have been investigated. Using an in situ double layer agar overlay system, we demonstrated that exposure of the stromal cells to 1,100-rad irradiation increased their activities in stimulating colony formation of FDC-P1, an interleukin 3 (IL 3)-responsive cell line. The colony-stimulating activities (CSAs) of the irradiated stroma also stimulated normal marrow cells to form granulocyte-macrophage, megakaryocyte, and mixed lineage colonies. Addition of the lectin pokeweed mitogen to the irradiated stroma increased the level of CSAs. The FDC-P1 CSA of the irradiated stroma was inhibited by antibodies directed against murine granulocyte- macrophage colony stimulating factor (GM-CSF) but not by those against murine IL 3. Stromal-derived CSA for marrow cells was also partially blocked by anti-GM-CSF antibodies, probably reflecting the presence of other CSAs such as CSF-1. This latter growth factor has been found to be present in conditioned media from Dexter stroma, but levels are not increased after irradiation or lectin exposure. Partially purified GM- CSF, like IL 3, stimulated FDC-P1 proliferation and granulocyte, macrophage, and megakaryocyte colony formation. These results indicate that the major terminal differentiating hormone elicited by irradiation or lectin exposure of murine marrow stromal cells is GM-CSF. This growth factor, along with CSF-1, can account for the differentiated progeny produced in this system: macrophages, granulocytes, and megakaryocytes.     

Human lung tissue as a source of colony stimulating activity

Summary Medium conditioned by human lung tissue was found to contain colony stimulating activity (CSA). This material was tested against mouse and human bone marrow as target system. Colony forming units (CFUc)from both species responded and gave rise to clonal growth in agar cultures. This colony formation was dose dependent and the relationship was a sigmoid one. Experiments to determine the molecular weight of human lung derived colony stimulating Factors brought evidence for four active molecular weight fractions with approximately 79000, 40000, 23000 and 2000 daltons. The 23000 dalton fraction activated human cells only, whereas the other fractions were active on both human and mouse bone marrow cells.     

Secretion of plasminogen activator by the human macrophage-like cell line, GCT: separation from colony-stimulating and erythropoiesis-enhancing activities

S ummary . The human macrophage-like cell line, GCT, elaborates monokines such as colony-stimulating activity (CSA) and erythropoiesis-enhancing activity (EEA) which stimulate the growth of primitive blood progenitors in culture. These cells also secrete a fibrinolysis activator (FA), which can be identified if cells are cultured in serum-free medium. FA was found to have a similar molecular weight to CSA and EEA by gel filtration but could be separated from them by ion exchange chromatography. Subcellular fractionation of GCT cells indicated that fibrinolytic activity was present in the cell membranes and cytosol, whereas CSA and EEA were present only in the cytosol. FA resembled urokinase in molecular weight and its strict requirement for plasminogen as a substrate. Double immunodiffusion of GCT activator and urokinase against anti-urokinase antiserum resulted in a line of identity, and incubation of activator with antiserum resulted in loss of its fibrinolytic activity. Thus, GCT activator was similar, if not identical to the plasminogen activator, urokinase.     

Release of granulocyte-specific colony-stimulating activity by human bone marrow exposed to phorbol esters

Granulocyte-macrophage colony growth depends on the presence of colony- stimulating activity (CSA). Phorbol esters induce concentration- dependent colony formation in the absence of exogenous CSA. We questioned whether phorbol esters mimicked the action of CSA by directly stimulating colony growth, or whether phorbol esters acted indirectly by inducing marrow cells to release CSA. First, after incubating human bone marrow cells with phorbol 12,13-dibutyrate (PDB) for 3 days, we separated PDB from the protein peak of the conditioned medium by Sephadex G-10 gel filtration and tested this peak for the presence of CSA. When diluted 1:10 in the agar colony assay, this material induced 133 +/- 15 colonies/10(5) bone marrow cells. Second, to determine whether bone marrow cells required the continued presence of PDB in order to release CSA, PDB was removed from bone marrow cells by washing, and these cells were reincubated in fresh medium in the absence of PDB. CSA was found in the medium of these cultures; its release was maximal after preincubation of bone marrow cells with 5 X 10(-8) M PDB for 3 days, followed by incubation for 3 days in the absence of PDB. This CSA stimulated granulopoiesis out of proportion to monocytopoiesis, with 85% +/- 17% of the colonies being granulocytic (as indicated by histochemical staining for chloroacetate esterase), and 12% +/- 3% being monocytic (as indicated by nonspecific esterase). Inhibitors of monocyte colony formation, including PGE1, were not present in the medium that contained this CSA. These studies demonstrate that normal human bone marrow cells exposed to PDB release CSA and that this CSA selectively stimulates granulopoiesis in vitro.     

Evidence that the macrophage-granulocyte inducer (MGI) is produced during cell proliferation, stored in G0, released in G1, cell specific, and induces the secretion of other colony-stimulating activities (CSA)

The secretion of the macrophage and granulocyte inducer (MGI), also known as colony-stimulating factor (CSF), by epithelial cells from lungs and kidneys, and by fibroblasts from lungs, was determined as a function of time in culture; it was found to be secreted during the initial exponential proliferation period, and not when the cells approached saturation density. When the cells were again induced to proliferate, large amounts of CSF were released after 3 h, thus hinting at the existence of a reserve pool. A CSF activity of 70,000 daltons was found in cultures of fibroblasts from lungs, kidneys, and the peritoneal cavity, a 45,000-dalton CSF was obtained from mouse peritoneal macrophages, and from bone marrow cells when activated for macrophage proliferation, and a 22,000-dalton CSF was found from epithelial cells, thus suggesting that the different CSFs are cell specific. When fibroblast CSF was used to induce bone marrow cells, three new molecules with colony-stimulating activity were produced, of 45,000, 30,000, and 17,000 daltons. The fraction with the 17,000-dalton activity also contained interleukin 1 activity, hinting at an indirect induction of colony formation by this factor. Finally the possible existence of a cascade reaction in which one CSF induces the appearance of other CSFs during the normal regulation of myeloid cell differentiation is discussed.     

Cell interactions influencing murine marrow megakaryocytes: nature of the potentiator cell in bone marrow

Auxiliary bone marrow cells are required for optimal murine megakaryocyte colony formation in addition to progenitor cells and a colony stimulating activity (CSA) present in WEHI-3 cell conditioned medium. These auxiliary cells are adherent, with a sedimentation rate of 5.8 mm hr-1 and buoyant density of 1.065-1.078 gcm-3. The activity from bone marrow cells is loss at irradiation doses above 900 rad. Bone marrow cells with these characteristics, and supernatants from lung, bone shafts, and peritoneal exudate cells were all active in enhancing megakaryocyte colony incidences in mouse bone marrow cultures above those stimulated by an obligatory activity in WEHI-3 cell conditioned medium. Certain macrophage cell lines (J774, P388D1) could elaborate the activity. This study confirms that a potentiation activity enhances CSA stimulation of megakaryocyte colony formation. The potentiator is elaborated by bone marrow cells in limiting amounts requiring either high cell concentrations or an exogenous source of the activity for optimal colony growth.     

Sequential effects of lithium on haematopoiesis

The administration of lithium salts to haematologically normal subjects is associated with increased blood neutrophil concentrations and marrow neutrophil production and with enhanced release of colony stimulating activity (CSA) required for growth of granulocyte-macrophage progenitor cells (CFU-GM) in vitro. To examine the haematopoietic changes associated with lithium salts, mice were given LiCl daily. Blood neutrophils and serum CSA levels increased as did blood platelet concentrations. These increments were preceded by expansion of marrow neutrophil production and increased concentrations of CFU-GM as well as progenitor cells for megakaryocytes (CFU-M) and erythrocytes (BFU-E and CFU-E). An earlier and sustained increase of transplantable pluripotential stem cells (CFU-S) was detected beginning at day 2 of lithium administration. The sustained increase of CFU-S with lithium was not associated with detectable changes of endogenous stem cells (E-CFU) suggesting that a portion of the stem cell pool is resistant to the proliferative effects of lithium. These studies indicate that lithium acts initially to directly or indirectly increase marrow CFU-S with later increments of progenitor cells. The more sustained increase of blood neutrophils with lithium administration may be the result of subsequent increments of CSA resulting in enhanced marrow granulocyte production.     

Adherent Cell Dependent Colony-Stimulating Activity in Human Serum: A Granulopoietic Regulator?

Bacterial infections and trauma which increase production of granulocytes and monocytes by the bone marrow, may do so through factors in serum capable of stimulating growth of granulocyte-macrophage cells in vitro. Human serum possesses two types of colony stimulating activity (CSA), one which stimulates granulopoietic progenitor cells directly, and another which results from the interaction of serum and bone marrow adherent cells (monocyte-macrophages) or peripheral blood leucocytes: adherent cell dependent CSA. These activities are due to different factors which may be separated by gel filtration. Sera of 7 patients undergoing hystectomy who developed post-operative infection showed post-operative elevation of the adherent cell dependent activity in all cases but no change in direct acting CSA. These results suggest that the direct acting CSA in human serum does not represent the principal humoral ‘message’ to the bone marrow from sites of trauma and infection in the tissues and that granulopoiesis may be controlled indirectly by the action of a different humoral factor which increases production of CSA by marrow monocyte-macrophages. Preliminary experiments suggest that lymphocytes stimulated by bacterial products may be one source of this factor.     

Characterization of colony-stimulating activity produced by human monocytes and phytohemagglutinin-stimulated lymphocytes

Human colony-stimulating activity (CSA) may support the proliferation of both human and murine granulocyte-macrophage progenitor cells (CFU- C) or, in the case of human urinary CSA, may only stimulate murine bone marrow CFU-C. CSA produced in the culture media of monocytes and macrophages and phytohemagglutinin-stimulated lymphocytes from human peripheral blood was characterized for both human and mouse marrow CFU- C stimulating activities. During the initial phase of a long-term cultures of monocytes, both human- and mouse-active CSA (MnCM-HM) were produced. In later phases of culture, however, only mouse-active CSA (MnCM-M) was produced. Fractionation on Sephadex G-150 revealed two functionally distinct species from MnCM-HM and lymphocytes conditioned medium, a high molecular weight factor (MW greater than 150,000) which stimulated mouse but not human colony formation, and a low molecular weight species (MW 25,000-35,000) which was active against both mouse and human target cells. However, MnCM-M revealed only one high molecular weight species (greater than 150,000), active only on mouse marrow. The possible biologic significance of such an activity is discussed.     

Molecularly cloned and expressed murine T-cell gene product is biologically similar to interleukin-3

Clonal lines of mouse inducer ly1+ly2- inducer T-lymphocytes that depend for growth upon interleukin-2 have been demonstrated to produce a factor that stimulates colony formation by bone marrow granulocyte-macrophage (GM-CFUc) progenitor cells and replication of factor-dependent mast cell/basophil and multipotential hematopoietic cell lines in vitro. The molecularly cloned and expressed gene product for this growth factor demonstrates the following activities in vitro: using fresh bone marrow or purified subpopulations of nonadherent cells from murine continuous bone marrow cultures as target cells: stimulation of colony formation by GM-CFUc, mast cell progenitor cells, multipotential granulocyte/erythroid/megakaryocyte/macrophage progenitor cells (CFU-GEMM) colonies, erythroid progenitor cells forming macroscopic bursts (BFUe), and megakaryocyte progenitor cells (CFU-mega). The gene product also supports growth of previously reported mast cell growth-factor-dependent cell lines and several classes of interleukin-3 (IL-3)-dependent hematopoietic progenitor cell lines that are multipotential (neutrophil/basophil/eosinophil or neutrophil/basophil/erythroid); or committed to granulocyte-macrophage, or mast cell/basophil differentiation. The gene product does not detectably support replication of IL-2-dependent murine T-cell lines. The biologic activity of the gene product was inhibited greater than or equal to 90% by rabbit antisera prepared against purified interleukin-3. The data indicate that this T-cell derived lymphokine gene product is biologically very similar to interleukin-3.     

Two different types of granulocyte colony-stimulating factor produced by bovine lung tissue

Summary Bovine lung tissue produces two different types of granulocyte colony-stimulating factor (CSF). The high molecular weight (MW) type (CSF-F) of 70,000 d by Sephadex G-100 gel filtration is only found in conditioned medium of homogenized tissue indubated in sealed glass bottles. This species of CSF exclusively stimulates CFU-C of mouse bone marrow, human bone marrow only hardly. The low MW type CSF (CSF-M) of approximately 29,000 d by gel filtration is found mainly in conditioned medium of slightly minced tissue incubated in Petri dishes. It stimulates both human and mouse CFU-C. Methods to prepare both types of CSF are described. By propagating a fibroblast cell line from bovine lung tissue it was found that fibroblasts are the source of the 70,000 d CSF. Indirect evidence suggests that macrophages produce the 29,000 d CSF species.Abbreviations BLCM bovine lung conditioned medium - CFU-C colony forming units in culture - CM conditioned medium - CSF colony stimulating factor - CSF-F colony stimulating factor produced by fibroblasts - CSF-M colony stimulating factor produced by macrophages - MLCM mouse lung conditioned medium - MW molecular weight - RPMI Roswell Park Memorial Institute (medium) - PBS phosphate balanced salt (solution) - SDS sodium dodecyl sulfate     

Augmentation of neutrophilic granulocyte progenitors in the bone marrow of mice with tumor-induced neutrophilia: cytochemical study of in vitro colonies

Transplantation of CE mammary carcinoma into mice has been shown to produce marked neutrophilia. Previous studies in vivo indicated a significant increase in marrow neutrophil production in these mice, but regulatory mechanisms of this neutrophilia have not been well understood. In order to obtain information about neutrophil production mechanisms at the progenitor cell level, the profile of marrow granulocyte-macrophage progenitors in mice with neutrophilia induced by this tumor was quantitatively analyzed by cytochemical staining of in vitro colonies to distinguish colonies of neutrophils (N-colony), macrophages (M-colony), and mixed cells (NM-colony). Cell cycle kinetics of progenitors were studied by in vivo administration of cytocidal drugs. The absolute number of N-colonies in a femur increased significantly and reached three times normal three to four weeks after tumor implantation. The number of NM-colonies also increased significantly by the fourth week, but the number of M-colonies was unchanged. The number of N-colonies in a femur related directly to the degree of neutrophilia. The increased number of N-colonies from the marrow of tumor-bearing mice was not attributed to a different time course of colony growth nor to a different sensitivity to CSA; instead, a significantly larger fraction of neutrophilic progenitors from the tumor-bearing mice were in active cell cycle than were those of normal mice. The day 14 tumor-bearing mouse serum demonstrated N-colony stimulating activity while the sera of normal mice and day 7 tumor- bearing mice were inhibitory for in vitro colony growth. These studies demonstrated an increase in the numbers and turnover rate of marrow neutrophilic progenitors in CE tumor-induced neutrophilia, suggesting that this tumor stimulates proliferation of these progenitors in vivo.     

Colony stimulating activity in the serum of patients with multiple myeloma is enhanced by interleukin 3: a possible role for interleukin 3 after high dose melphalan and autologous bone marrow transplantation for multiple myeloma

Sera from 36/37 multiple myeloma patients and 19/21 sera from patients with other solid or liquid tumours had granulocyte-macrophage colony stimulating activity (CSA) towards normal human donor bone marrow whereas 1/16 sera from normal donors had this activity. Unlike human rhGM-CSF and GM-CSF from 5637 (human bladder cell line) conditioned medium which is heat stable, CSA from serum is heat labile (56 degrees C/30 min). In multiple myeloma patients, CSA was detectable more than 2 years after treatment with 'high dose melphalan. Although multiple myeloma patients, at relapse, have sufficient CSA in their serum to produce maximal stimulation of GM-CFUc from normal donor bone marrow in vitro, their own GM population responds poorly. The results suggest that the failure of patients own bone marrow to respond to endogenous CSA may be due to damage to the stem cells of the marrow or the failure of precursor cells to respond to CSA. Addition of rhIL-3 to myelomatous serum increased the number of GM-CFUc from both normal and myelomatous bone marrow but did not stimulate the growth of MY-CFUc significantly. The results suggest that rhIL-3 may assist bone marrow recovery in multiple myeloma patients after intensive chemotherapy.     

Clonal analysis of the response of human myeloid leukemic cell lines to colony-stimulating activity

The recent development of two continuously proliferating human myeloid leukemic cell lines (HL-60 and KG-1) that response to CSA provides an opportunity for a detailed study of the interaction of CSA with leukemic myeloid cells. Here we report on the colony-forming ability of HL-60 and KG-1 over an extended culture life of the cells. Several different sources of human CSA of different stages of purity enhanced colony formation of these cells. CSA, obtained from conditioned media from an SV-40 transformed human trophoblast, was partially purified, and its activity for normal bone marrow copurified with the activity that stimulated HL-60 colony formation. Over 100 clones of HL-60 were developed and tested for their response to CSA. All responded to CSA by showing an increase in colony size and number. However, none of the colonies formed from any of the 100 clones differentiated in response to CSA despite the fact that many chemical can induce differentiation of HL-60. since HL-60 forms spontaneous colonies without the addition of any exogenous stimulating factors, HL-60 conditioned media and cell extracts were tested for the production by these cells of their own endogenous growth-promoting activity (such as a CSA-like molecule). No growth-promoting endogenous activity was found that stimulated normal bone marrow or HL-60 colony formation even after concentration and fractionation methods were employed. These experiments suggest that: (1) the effect of CSA markedly favors proliferation over differentiation in these cell lines; (2) CSA is unlikely to suppress growth of the age of the type of leukemic myeloid cells that HL-60 and KG-1 represent; and (3) if HL-60 cells produce their own growth- promoting factor it is not detectable in the media.     

The effects of tumor-promoting phorbol esters on human granulopoiesis in vitro

In order to determine whether the tumor-promoting phorbol esters are capable of inducing normal human committed granulocytic-monocytic progenitor cells (CFUc) to proliferate and differentiate in the absence of granulocyte-monocyte colony-stimulating activity (CSA), we studied the effects of these compounds on human granulopoiesis in vitro. We found that when light-density human marrow cells or peripheral blood leukocytes were depleted of adherent cells and then incubated in semisolid tissue culture medium under conditions optimal for CFUc growth, phorbol myristate acetate (PMA) and its congeners produced no measurable stimulatory effect on the proliferation of CFUc in the absence of added CSA. Likewise, when light-density marrow cells that had not been depleted of adherent cells were plated in the cultures, no stimulation of CFUc colony growth resulted from the addition of PMA. However, when light-density peripheral blood leukocytes were used as a target source of CFUc without first subjecting them to adherence separation, enhanced proliferation and differentiation of CFUc were noted in cultures that contained PMA. To investigate the possibility that CSA production by monocytes in these cultures in response to activation by PMA might account for the enhanced colony formation that we observed, we incubated isolated peripheral blood monocytes in short- term liquid suspension cultures and found that in the presence of PMA, large quantities of CSA were secreted into the surrounding medium. Finally, we noted that when marrow cell suspensions were suboptimally stimulated by low concentrations of CSA added to the cultures, the effects of PMA on CFUc proliferation were unpredictable, enhancing colony formation in some cases and inhibiting it in others. Our data indicate that although the tumor-promoting phorbol esters do not appear capable of directly stimulating the proliferation or differentiation of human CFUc in the absence of CSA, they may do so indirectly by causing auxiliary cells such as monocytes to secrete CSA.     

Humoral factors modulating growth of granulocyte macorphage progenitor cells.

The kinetic of production of colony-stimulating activity (CSA) inducing mouse and human colony-forming cells (CFU-C) was tested in different human leukocyte culture systems. Stimulated and unstimulated cultures of spleen single cell suspensions, peripheral mononuclear leukocytes and acute monocytic leukemia (AMoL) cells were investigated. With the exception of the AMoL cells, stimulated cultures always revealed higher CSA levels than unstimulated controls. The spleen cell cultures exhibited the highest overall activity showing three molecular species of 70,000, 35,000 and 10,000 daltons activating human CFU-C to form colonies in the agar culture system. Furthermore it could be demonstrated that colony formation could be inhibited by low molecular weight fibrinogen degradation products obtained by digestion of fibrinogen with granulocyte-derived elastase.     

The regulatory role of interleukin 2-responsive T lymphocytes on human marrow granulopoiesis

The effect of recombinant interleukin 2 (IL2) on marrow CFU-C colony formation was evaluated to define the role for T lymphocytes in human marrow granulopoiesis. The colony-stimulating factor (CSA) used in our experiments was found to contain IL2. IL2 depletion from CSA resulted in a reduction in CFU-C colony proliferation. Addition of exogenous IL2 caused an increase in CFU-C colony numbers in a dose-dependent manner. This increase could be prevented by anti-Tac, a monoclonal antibody (MoAb) to the IL2 receptor. Moreover, anti-Tac in the absence of exogenous IL2 resulted in an overall decrease in colony numbers. Depletion of either adherent cells or T lymphocytes abolished the effect of IL2 and anti-Tac on colony growth. In the presence of IL2, re- addition of T lymphocytes to the T-depleted marrow or adherent cells to adherent cell-depleted marrow resulted in a significant increase in CFU- C colony numbers, whereas no significant effect was found when IL2- depleted CSA was used. Although T lymphocytes were not themselves essential for CFU-C colony growth, our studies indicate that IL2 and IL2-responsive T cells can regulate in vitro granulopoiesis.