Factors regulating macrophage production and growth: identity of colony-stimulating factor and macrophage growth factor

Occurrence of a monocyte/macrophage colony-stimulating factor in the continuous ambulatory peritoneal dialysis fluids and its chromatographic behaviors and antigenicity compared with human urinary colony-stimulating factor

Continuous ambulatory peritoneal dialysis (CAPD) fluid from three patients with chronic renal failure exhibited the activity of colony-stimulating factor (CSF) in amounts varying from 5 to 40 units per ml. Like the CSF obtained from normal human urine, the peritoneal CSF predominantly produced monocyte/macrophage colonies in soft-agar culture of mouse bone marrow cells. Semipurified peritoneal CSF showed its isoelectric point at pH 3.6 and 4.9 before and after the treatment with neuraminidase. Under the same conditions, the urinary CSF was focused at pH 3.1 and 4.6. The position of elution of the peritoneal and urinary CSF in ordinary gel-filtration chromatography corresponded to a molecular weight of 62,000 and 117,000, whereas both CSFs exhibited a molecular weight of 28,000 upon gel-filtration in the presence of 6 M guanidine HCl. Furthermore, the two CSFs from the human sources were neutralized by antimouse L cell CSF serum in the same manner. We conclude that the peritoneal CSF is a sialoglycoprotein which is nearly identical with the urinary CSF despite processing of the latter through kidneys.

Modulation of myelopoiesis in vivo by synthetic adjuvant-active muramyl peptides: induction of colony-stimulating activity and stimulation of stem cell proliferation

Modulation of myelopoiesis by three synthetic muramyl peptides was investigated in vivo. Two adjuvant-active compounds (N-acetylmuramyl dipeptide [MDP] and MDP-butyl-ester) elicited significant responses in DBA/2 mice characterized by a rise in the level of monocyte-macrophage colony-stimulating activity in serum, a proliferation of multipotential stem cells in the bone marrow, and an expansion of granulocyte-macrophage progenitors in the spleen. In contrast, the adjuvant-inactive stereoisomer MDP(D-D) induced only low levels of circulating colony-stimulating activity. Thus, MDP or MDP-butyl-ester injection could induce a greater number of macrophages and therefore enhance both specific and nonspecific immunity.

Optimal conditions for proliferation of bone marrow-derived mouse macrophages in culture: the roles of CSF-1, serum, Ca2+, and adherence

A method is described for the analysis of [3H]-thymidine incorporation in microtitre cultures of bone marrow-derived mouse macrophage responding to macrophage colony-stimulating factor (CSF-1). [3H]-thymidine incorporation depends on cell density, culture medium, and the concentration of CSF-1 and serum, but is independent of Ca2+. Bone marrow-derived macrophages are strongly adherent, but adherence can be dissociated from [3H]-thymidine incorporation.

The regulation of macrophage protein turnover by a colony stimulating factor (CSF-1)

CSF-1 is a hemopoietic growth factor that specifically regulates the survival, proliferation, and differentiation of mononuclear phagocytic cells. A homogeneous population of mononuclear phagocytes, bone marrow derived macrophages (BMM), were used to study the regulation of protein turnover by CSF-1. Removal of CSF-1 (approximately 0.4 nM) from exponentially growing BMM cultured in 15% fetal calf serum containing medium decreases the rate of DNA synthesis by more than 100-fold. Addition of CSF-1 to these cells causes them to resume DNA synthesis within 12 h. More immediate effects of CSF-1 were observed on BMM protein metabolism. BMM cultured for 24 h in the absence of CSF-1 reduce their protein synthetic rate by 50-60%. The protein synthetic rate commences to decrease at 2-3 h after CSF-1 removal. Readdition of CSF-1 to BMM previously incubated in its absence causes a return to the protein synthetic rate of exponentially growing cells within 2 h. In the presence of CSF-1, BMM synthesize protein at a rate of approximately 8.7%/h and degrade it at a rate of approximately 0.9%/h. Removal of CSF-1 results in a decrease in the protein synthetic rate to approximately 3.4%/h and an increase in the rate of protein degradation to approximately 3.4%/h. The rate of protein synthesis by BMM increases linearly with CSF-1 concentration over the range of concentrations stimulating both survival and proliferation, while the rate of protein degradation decreases exponentially over the range of concentrations stimulating survival without proliferation. Therefore, it appears that the stimulation of the rate of protein synthesis and inhibition of the rate of protein degradation are two distinct effects of CSF-1, both part of the pleiotropic response to this growth factor. The inhibition of the rate of protein degradation by CSF-1 may be most significant for its survival inducing effect.

Glucocorticoids and prostaglandins inhibit the induction of macrophage DNA synthesis by macrophage growth factor and phorbol ester

The tumor-promoting phorbol ester, 12-0-tetradecanoyl-phorbol-13-acetate (TPA), stimulates starch-elicited mouse peritoneal macrophages to undergo DNA synthesis in vitro, apparently without the generation of an endogenous macrophage growth factor (MGF). No evidence was found for any synergistic interaction between TPA and exogenous colony stimulating factors (CSFs) for macrophage DNA synthesis. Low concentrations of glucocorticoids and also prostaglandins E1 and E2 suppress both the CSF-1-stimulated and the TPA-stimulated macrophage DNA synthesis; these same drugs inhibit the CSF-1-mediated and TPA-mediated enhancement of macrophage plasminogen activator (PA) activity. Thus glucocorticoids and prostaglandins E1 and E2 oppose the action of growth factors and the tumor promoter on macrophage and precursor cell function.

Renal disease profoundly alters cortical interstitial cell function

Interstitial cells were cultured from explants of the unilaterally hydronephrotic, contralateral, and normal kidneys. Two types of cells were identified in culture, macrophages, and cells which were tentatively identified as fibroblasts. Cells grew at a significantly faster rate in hydronephrotic compared to contralateral or normal kidneys. Cells from the hydronephrotic kidney increased prostaglandin (PG)E2 production in response to bradykinin. Cells from contralateral and normal renal cortex did not increase PGE2 production in response to bradykinin. These results indicate hydronephrosis induces functional changes in interstitial cells cultured from the cortex of hydronephrotic compared to contralateral and normal kidneys. The induction of increased PGE2 synthesis and bradykinin responsiveness in hydronephrotic cortex could be related to the exaggerated prostaglandin synthesis known to occur in hydronephrotic cortex. In hydronephrosis, cortical interstitial cells elaborate increased amounts of substances such as prostaglandins which have the capacity to modulate important parameters of renal function.

Endocytosis by the mononuclear phagocyte system and autoimmune disease

The mononuclear phagocyte system, formerly called the reticuloendothelial system, is an important element in basic immunology, cell biology, and clinical disease. Secretory products participate in inflammation and immunoregulation. Endocytosis mediated by specific receptors for immunoglobulin and complement or by other opsonins is important in removal of damaged self or foreign particles. The ability to assess receptor-specific endocytosis has led to the recognition of Fc-receptor dysfunction in certain autoimmune diseases. This defect in membrane receptor function, whether inherited or acquired, may be important in the pathogenesis of these diseases.

Cell hybrids between SV40-transformed macrophage cell lines and a Chinese hamster cell line: growth responsiveness and induction of colony-stimulating factor

Three cell lines from resident macrophages of BALB/c mice and four from activated macrophages of the same strain were isolated by infection with simian virus 40 (SV40). A majority of these cells showed dependency on L cell-conditioned medium (LCM), which is necessary for proliferation of normal macrophages in vitro. Somatic cell hybridization was applied in the study of macrophage growth responsiveness. A macrophage cell line (BR15) with strict dependency on LCM for growth was fused to a Chinese hamster cell line (hs222-16); it was found that dependency on LCM was a dominant trait in the hybrids. Following fusion of a macrophage cell line (BAM3) which grew without LCM to hs222-16, a large number of colonies appeared in the selection medium containing LCM. Four hybrids not requiring LCM for growth were selected in an LCM-free culture, and their hybrid properties were examined. Three out of the four hybrids secreted colony-stimulating factor (CSF) constitutively, whereas the fourth secreted no CSF. The level of acid phosphatase activity in the hybrids was higher than in the parent cells. Two peaks of CSF activity were observed after gel filtration chromatography of conditioned medium: One was eluted at molecular weight of 36,000 and the other at 17,000.

Colony-stimulating factors and regulation of macrophage tumoricidal and microbicidal activities

Conditioned medium from antigen- or mitogen-stimulated spleen cells, lymphokines, contained factors that induced formation of granulocyte and macrophage colonies in cultures of bone marrow cells (CSF). Lymphokines also contained factors that induced macrophage non-specific tumoricidal activity against fibrosarcoma 1023, antibody-dependent tumoricidal activity against lymphoma 18-8, and antimicrobial activities against amastigotes of the protozoan parasite, Leishmania tropica. The factors that regulated macrophage effector functions, however, were different from those that induced colony formation, and could be distinguished from CSF by Sephadex gel chromatography or heat sensitivity. To further analyze a role for CSF in induction of macrophage effector activities, conditioned medium from several nonlymphoid cell sources (L-929, WEHI-3, and endotoxin-treated lung cells) were assayed for CSF activities and capacity to induce tumoricidal and microbicidal activities. Conditioned medium that contained either macrophages CSF (CSF-1) or the factor that induced formation of both macrophage and granulocyte colonies failed to activate macrophages for effector activities against fibrosarcoma 1023, lymphoma 18-8, and L. tropica amastigotes (either resistance to infection or intracellular destruction). These data suggest that CSF has no direct role in activation of macrophages for tumoricidal and microbicidal activities against these targets.

Thromboplastin as a marker for monocyte differentiation

The thromboplastin synthesis of the human monocytoid cell line U-937 and its two subclones designated U-937-3 and U-937-4 has been studied. U-937-4 seems by several functional criteria to represent a more advanced stage of monocyte differentiation than the original U-937. U-937-3 appears to be arrested at an even more immature stage than the original population. The basal thromboplastin activity was higher in U-937-4 than in U-937-3 or U-937 cells (7.0 +/- 1.9 (SEM), 1.0 +/- 0.2 and 1.6 +/- 0.6 units/mg protein, respectively) although not as high as in human normal monocytes (14.1 +/- 2.4). The thromboplastic expression of the two clones was maximal when cells were in logarithmic growth. Both clones responded with a weak to moderate thromboplastin synthesis upon addition of stimulants like phytohaemagglutinin (PHA), immune complexes or endotoxin. Thromboplastin production was also potentiated in the presence of lymphocytes. The supporting effect of lymphocytes was strong in the case of U-937-3 as well as in U-937 cells, but less pronounced in U-937-4 cells as it also is in human monocytes. The thromboplastin response after PHA stimulation was more rapid in U-937-4 cells (maximal after 4-8 h) than in U-937 or U-937-3 cells (12-16 h). Human monocytes also responds quickly to PHA (maximally 4 h). Total phospholipid content and the relative distribution of individual phospholipids were essentially similar in U-937-3, U-937-4 and U-937. With regard to thromboplastin production, U-937-4 cells seem to be more monocyte-like than the more immature cells U-937-3 and U-937. It is concluded that thromboplastin seems to be a useful marker for monocyte differentiation.

Regulation of plasminogen activator secretion, interferon induction and proliferation in murine macrophages

The purpose of this work was to study the interrelationship of proliferation and secretion of plasminogen activator (PA) and interferon (IFN) by murine macrophages. For induction of macrophage proliferation and secretion of PA, concanavalin A (Con A) was used. Secretion of IFN was induced by polyinosinic polycytidylic acid complex. The glucocorticoid dexamethasone acetate (DA) (10(-6)-10(9) M) inhibited Con A-stimulated secretion of PA and synthesis of DNA as evaluated by incorporation of [3H]thymidine. DA did not inhibit IFN induction. Preincubating macrophages with DA for 45 h reduced basal proliferation and secretion of PA but did not reduce responsiveness to Con A. Also retinoic acid, a modulator of carcinogenesis was used in inhibition studies because of its known antagonistic effects on lymphocyte mitogenesis. In macrophages a biphasic effect of retinoic acid (1 X 10(-5) - 5 X 10(-5)M) was found: (a) inhibition of DNA synthesis and secretion of PA during the first 45 h of incubation, and (b) enhancement of DNA synthesis (but not PA secretion) after 72 h. Secretion of IFN was not affected. It is suggested that secretion of PA but not IFN is linked to cell cycle traverse of macrophages.

Purification of a human urinary colony-stimulating factor

Colony-stimulating factor (CSF), a protein required for the in vitro formation of colonies composed of granulocytes and/or macrophages, was isolated from the urine of anemic patients by using a seven-step procedure. The purified, homogeneous CSF had a specific activity of 1.9 X 10(8) U/absorbance unit at 280 nm (AU). This represents an overall purification of 25,330-fold and a total recovery of 3.8%. Upon iodination of the protein, the radioactivity migrated on sodium dodecyl sulfate (SDS) gel electrophoresis as a single peak with an apparent molecular weight of 46,000; reduction with mercaptoethanol caused dissociation to a single component of molecular weight 23,000. Only the dimer is active in stimulating colony formation. Urinary CSF stimulates formation of colonies comprising only macrophages in the mouse bone marrow cell culture assay. A neutralizing antibody raised against mouse L-cell CSF did not neutralize the activity of the urinary CSF but did bind it. This may indicate that the relative positions of antibody binding sites and the active sites are different in these two glycoproteins.

Synthesis of thromboplastin by U-937 cells

A human monocytoid cell line (U-937) produces a procoagulant identified as thromboplastin when stimulated with phytohaemagglutinin (PHA), endotoxin, immune complexes, the phorbol ester 12-O-tetradecanoyl-phorbol 13-acetate (TPA) or the divalent ionophore A 23187. The basal thromboplastin expression of these cells and the increased activity induced by the stimulants were dependent on supply of fresh medium suggesting that the synthetic rate was highest when the cells were in logarithmic growth. Inducible thromboplastin synthesis was inhibited by actinomycin D or cycloheximide, indicating dependence on messenger RNA and protein synthesis. Differentiation of the cells in the macrophage direction by TPA did not make the cells more responsive to PHA. Thromboplastin induction in U-937 cells was potentiated by the presence of lymphocytes, especially when stimulated with PHA or endotoxin. This supporting effect was also obtained by conditioned medium from lymphocyte cultures, suggesting a role for a soluble lymphocyte product.

Production of monocyte/macrophage colony-stimulating factor by preadipocyte cell lines derived from murine marrow stroma

Three preadipocyte cell lines that have been independently derived from bone marrow stroma (Lanotte et al, 1982) have been tested for their capacity to produce granulocyte, macrophage, and erythroid colony-stimulating factors (CSFs). All elaborated colony-stimulating material that was active upon adult mouse marrow granulocyte/macrophage colony-forming cells (M-CFC) but not foetal liver GM-CFC. The major activity was characterised as a monocyte-macrophage colony-stimulating factor (M-CSF), and the pattern of colony stimulation was similar to that seen after addition of highly purified L-cell CSF. Furthermore, the stimulating activity was specifically neutralised by rabbit anti-L cell CSF antibodies. No evidence was found for stimulation of multipotential or erythroid colony-forming cells, only few granulocytic colonies were detected, and the stimulating activity had no mouse strain restriction. All cell lines produced large quantities of M-CSF; however, the production was found to be modulated during the adipogenesis process. A peak in M-CSF production corresponded to the period of growth arrest after confluence of the stromal cells was reached and when adipocyte maturation was at an early stage. A marked depression in M-CSF secretion was associated with the final steps of adipocyte maturation.

Effects of serum fractions on the growth of mononuclear phagocytes

The effects of serum fractions on the growth kinetics and colony formation of mononuclear phagocytes derived from mouse bone marrow, blood, and peritoneal cavity were investigated. Peritoneal exudate macrophages and blood monocytes required a factor(s) found to reside in the nondialyzable serum fraction (molecular weight greater than 12,000) to survive, a small molecular weight (less than 307) factor(s) with growth-stimulatory activity (GSA) contained in the dialyzable serum fraction, and the macrophage growth factor (MGF) for proliferation and colony formation. Fetuin, a major protein of fetal serum, was able to substitute the nondialyzable serum fraction. Macrophages cultured in medium containing MGF and the nondialyzable serum fraction for 6 days could be restored to full growth following the addition of the dialyzable serum fraction. In contrast, bone marrow mononuclear phagocytes cultured in the absence of the dialyzable serum fraction were capable of proliferating, though at a slower rate, and forming colonies. In addition, neither insulin nor hydrocortisone was capable of replacing the serum-dialyzable GSA nor able to enhance colony formation.

Stimulation of monocyte production by an endogenous mediator induced by a component from Listeria monocytogenes

A monocytosis-producing activity (MPA) is present in a saline-extractable material (SE) from Listeria monocytogenes. The mechanism of stimulation of monocyte production by SE was studied. Serum obtained from mice at appropriate times after injection of SE induced monocytosis in normal recipients. The monocytosis-inducing activity present in serum differed from SE with respect to timing of the monocytosis, fractionation pattern on a Sephadex G-200 column, and thermolability. The minimum dose of SE capable of producing a monocytosis was 100 micrograms. Antibody to SE capable of detecting SE at a concentration of greater than 5 micrograms/ml failed to detect SE in samples of active serum. Therefore it seemed highly unlikely that activity in serum was due to the presence of trace amounts of SE. The activity present in serum was thermolabile and had a molecular weight of about 38,000. The data are consistent with the hypothesis that injection of SE caused the production or release of an endogenous mediator capable of stimulating monocytosis.

Regulation of monocyte precursor cell proliferation by two endogenous factors

The rather narrow variation in the number of mononuclear phagocytes in blood and tissues under steady-state conditions attests to a fine tuning mechanism regulating monocyte production and distribution. Some factors, such as CSF, prostaglandins, and lactoferrin, which are thought on the basis of in vitro findings to control homeostasis of the mononuclear phagocyte system, are reviewed, confirmation of the physiologic role of these factors will require in vivo studies. Under conditions leading to an increased demand for macrophages in tissues, large numbers of monocytes are produced in the bone marrow. Two endogenous factors, i.e. the factor increasing monocytopoiesis (FIM) and the monocyte production inhibitor (MPI), have been found to regulate monocytopoiesis in vivo during an inflammation. FIM occurring in the circulation during the initial phase of the inflammatory reaction is a protein that has no colony-stimulating activity, is cell-line specific, and stimulates the mitotic activity of the promonocytes and probably also the proliferation of the monoblasts. Macrophages produce and secrete FIM. MPI occurs in the circulation during the second phase of an inflammation. Although with the present assays these factors are only demonstrable during inflammation, which indicates that FIM and MPI are regulators of monocytopoiesis under increased demand, their possible role in control of homeostasis under normal steady-state conditions is not yet clear.

The activation of cloned macrophages by concanavalin A for tumoricidal effect: assessment of tumor cell cytotoxicity by a clonogenic assay

The activation of pure populations of cloned peritoneal macrophages for tumor cell cytotoxicity by Con A was demonstrated using a recently developed tumor cell clonogenic assay. Cloned macrophages were rendered cytotoxic by Con A at concentrations above 20 micrograms/ml. The tumor cell cytotoxicity was caused mainly by the tumoricidal activity of the Con A-activated cloned macrophages. Increasing The Con A-activation time from 24 hours to 48 hours and 72 hours heightened the cytotoxic activity of cloned macrophages. Cloned macrophages incubated with con A for only 2 hours possessed no cytotoxic effect. Culture fluid from cultures of activated macrophages exerted no tumor cell cytotoxicity. Alpha-methyl-D-mannoside, a specific receptor-binding inhibitor for Con A, was capable of blocking the activation of macrophages for cytotoxicity at 0.01 M concentration.

Immunoenhancing activity of NPT 15392: a potential immune response modifier

NPT 15392, a new immunomodulating compound related to inosine in structure and isoprinosine in action, enhances T-cell dependent immune responses. Antibody responses to sheep red blood cells are augmented two to threefold in mice receiving NPT 15392 while T-cell independent antibody responses to TNP-LPS are unaffected. NPT 15392 does not enhance or alter the number of clonable B cells. This drug also increases cytotoxic T-lymphocyte responses to allogeneic tumor cells but does not alter the number of cytotoxic precursor cells. Immature hematopoietic cell classes (clonable progenitor cells) were also monitored and found not to be influenced by NPT 15392.

Distribution of cells bearing receptors for a colony-stimulating factor (CSF-1) in murine tissues

CSF-1 is a subclass of the colony-stimulating factors that specifically stimulates the growth of mononuclear phagocytes. We used the binding of 125I-CSF-1 at 0 degrees C by single cell suspensions from various murine tissues, in conjunction with radioautography, to determine the frequency of binding cells, their identity, and the number of binding sites per binding cell. For all tissues examined, saturation of binding sites was achieved within 2 h at 2--3 x 10(-10) M 125I-CSF-1. The binding was irreversible and almost completely blocked by a 2 h preincubation with 5 x 10(-10) M CSF-1. 125I-CSF-1 binding was exhibited by 4.3% of bone marrow cells, 7.5% of blood mononuclear cells, 2.4% of spleen cells, 20.5% of peritoneal cells, 11.8% of pulmonary alveolar cells and 0.4% of lymph node cells. Four morphologically distinguishable cell types bound 125I-CSF-1: blast cells; mononuclear cells with a ratio of nuclear to cytoplasmic area (N/C) greater than 1; cells with indented nuclei; and mononuclear cells with N/C less than or equal to 1. No CSF-1 binding cells were detected among blood granulocytes or thymus cells. Bone marrow promyelocytes, myelocytes, neutrophilic granulocytes, eosinophilic granulocytes, nucleated erythroid cells, enucleated erythrocytes, and megakaryocytes also failed to bind. The frequency distribution of grain counts per cell for blood mononuclear cells was homogenous. In contrast, those for bone marrow, spleen, alveolar, and peritoneal cells were heterogeneous. The monocytes in blood or bone marrow (small cells, with either indented nuclei or with N/C greater than 1) were relatively uniformly labeled, possessing approximately 3,000 binding sites per cell. Larger binding cells (e.g., alveolar cells) may possess higher numbers of receptors. It is concluded that CSF-1 binding is restricted to mononuclear phagocytic cells and their precursors and that it can be used to identify both mature and immature cells of this series.

Induction of macrophage DNA synthesis by phorbol esters

Tumor-promoting phorbol esters, such as 12-0-tetradecanoylphorbol-13-acetate (TPA), stimulate mouse peritoneal exudate macrophages to undergo DNA synthesis without added macrophage growth factor (MGF). Resident peritoneal macrophages do not respond in this manner. Plasminogen activator (PA) levels of both exudate and resident peritoneal macrophages are elevated by TPA. Thus the phorbol esters appear to mimic the action(s) of MGF and may be useful in understanding the events involved in macrophage and precursor cell growth responsiveness.

The induction of human peripheral blood lymphoid colonies by conditioned media from human tumour cell lines

Conditioned medium (CM) from 29 human tumour cell lines and 3 malignant pleural fluids were tested for their ability to stimulate lymphoid colony formation in semi-solid agar; 9 of 14 malignant melanomas, 3 of 6 colonic carcinomas, 2 of 5 ovarian carcinomas, 3 of 4 breast carcinomas and 1 of 3 pleural fluids from breast cancer patients contained colony-stimulating activity (CSA) for human peripheral blood lymphoid cells (PBL) in semi-solid agar. Conditioned media also stimulated PBL proliferation in liquid medium; these effects were dose dependent. With the exception of one pleural fluid, extensive dialysis of CM did not significantly increase colony formation; CM from two tumour cell lines demonstrated a significant decrease in the induction of colony formation after dialysis.

Sequential expression of functions during macrophage differentiation in murine bone marrow liquid cultures

In the presence of a colony-stimulating factor, murine bone marrow cells proliferate and differentiate into macrophages. This culture system was taken as a model to study the expression of various functions by macrophages in the course of maturation. Several tests were performed daily and in parallel from the same batch of cells. It was found that certain functions were expressed early and were also characteristic for mature macrophages such as Fc receptors, phagocytosis of latex beads and unspecific esterase activity. Other functions appeared and disappeared in an ordered sequence, such as the response to macrophage migration inhibitory factor and chemotactic factor as well as the production of interferon and of plasminogen activator. The time course of functional expression was strongly dependent on proliferation of precursor cells as well as proliferation of differentiated macrophages. It is suggested that the phenotypic expression of functions during differentiation is the basis for the functional heterogeneity of macrophages.

Medium conditioned for 24 hours by mononuclear human blood cells contains an inducer of granulopoiesis lacking colony stimulating activity

Regulation of granulocyte and macrophage formation was studied by a modified CFU-C assay. Mouse bone marrow cells were cultured in methylcellulose in vitro. After colony counting on d 7, the cells were washed out to determine the total cell number per plate, and the distribution of granulocytes and macrophages in smears. By this procedure it was possible to study pathway-specific regulators. The colony stimulating factor in medium conditioned by mouse L-cells appeared specific for the macrophage cell line; 99% of the colony cells were macrophages. Medium conditioned for 24 h by mononuclear cells from human blood, had no colony forming capacity, but increased colony size and generated significant granulocyte production when combined with L-CSF. This granulopoiesis inducing factor was thermo-labile, and was mostly retained by an Amicon filter separating molecules at 100 000 daltons.

Chemical and biological properties of a growth factor from human-cultured osteosarcoma cells: resemblance with platelet-derived growth factor

A human osteosarcoma cell line, U-2 OS, cultured under serum-free conditions, was shown to produce a growth factor (osteosarcoma-derived growth factor, ODGF) for human-cultured glial cells, fibroblasts, and other cells. ODGF, collected from the spent medium of 2 OS cultures, was purified by a sequence involving heparin-Sepharose chromatography, hydrophobic chromatography, gel chromatography, and preparative gel electrophresis in SDS. Purified ODGF, at a concentration of 3 ng/ml, elicited a mitogenic response in human glial cells equivalent to 50% of that afforded by human serum at a final concentration of 1%. The preparation was estimated to be > 50% pure. The biological activity of ODGF resided in a cationic, relatively heat-resistant, reduction-susceptible protein with a molecular weight of 30,000 (by gel chromatography and SDS-gel electrophoresis). The electrophoretic behaviour of radioiodinated ODGF suggested that the protein was composed of two different polypeptide chains (about 13,000-14,00 and 16,000-17,000 daltons, respectively) linked via disulphide bonds. The molecular makeup of ODGF was thus similar to that of platelet-derived growth factor. 125I-ODGF could be precipitated by an antibody to platelet-derived growth factor, indicating that the two factors were immunologically related. Resemblance with platelet-derived growth factor was also indicated by the finding that the latter (but not, e.g., fibroblast growth factor or epidermal growth factor) competed with 125I-ODGF for binding to human-cultured glial cells.

[Humoral factors in the regulation of cell proliferation in haematopoiesis. I. Granulopoiesis and lymphopoiesis (author's transl)]

Humoral Factors obviously play an important role in the maintenance of the steady state in haematopoiesis. There has been work on stimulators and inhibitors for several years. Colony-stimulating factor is the best characterized chemically and biologically. Interest in more or less cell-line-specific stimulators and inhibitors of lymphopoiesis is now growing. Various tissue extracts and cell culture supernatants have been partially purified and characterized biologically and chemically. Monocytes, producing stimulators and inhibitors, have a central function in the regulation of cell proliferation in haematopoiesis. Experiments performed in vitro can help better to understand data so far difficult to explain regarding patients with disturbed haematopoiesis. The in vivo relevance of these experiments, however, remains unclear.

Haematopoietic growth factors are released in cultures of H-2-restricted helper T cells, accessory cells and specific antigen

Colony formation by mammalian haematopoietic cells in culture depends on specific glycoprotein growth factors. 'Colony-stimulating factors' for granulocytic and macrophage precursors (G- and M-CSFs), as well as for pluripotential and early committed erythroid cells ('burst promoting activity, or BPA) are released in cultures of stimulated spleen, lymph node or peripheral blood cells. In such systems the induction stimulus has been either allogenic cell antigens, or lectins which stimulate T cells, such as pokeweed mitogen, concanavalin A (Con A) or phytohaemagglutin and both T cells and adherent cells are implicated in the process. The complexity of the spleen cell populations used in earlier in vitro studies has made it difficult to establish the cellular source of the factors and the mechanisms leading to their release. Pure populations of continuously growing cell lines of either monocytic/macrophage or T-cell character have already been shown to release haematopoietic activities constitutively. However, such evidence cannot prove that these functions are also expressed by the normal counterparts of these lines. We have reduced the complexity of the spleen cell system by supplying helper T cells in the form of pure clonal populations of known physiological function and antigenic specificity, and demonstrate here that activity is released when helper T cells are cultured with specific antigen, and that release depends on H-2 (I-A region) restricted interaction with accesory cells present in spleen or normal peritoneal cavity.

Discrimination of a colony stimulating factor subclass by a specific receptor on a macrophage cell line

Utilizing the high affinity interactions between pure 125I-L cell colony stimulating factor and its receptor(s) on the murine macrophage cell line J774, a murine radioreceptor assay (RRA) has been developed. The murine RRA selectively detects a colony stimulating factor (CSF) subclass (CSF-1) previously defined by murine radioimmunoassay (RIA) (E.R. Stanley, Proc. Nat. Acad. Sci., USA, 76:2969-2973 ('79)). CSF-1 stimulates macrophage production exclusively, and the occurrence of the CSF-1 receptor(s) appears to be restricted to cells of the mononuclear phagocytic system (L.J. Guilbert and E.R. Stanley, J. Cell Biol. 85:153-160 ('80)). The murine CSF-1 RRA failed to detect a variety of other CSF subclasses, growth factors, and hormones. In contrast to data obtained with the murine CSF-1 RIA, human CSF-1 (e.g., human urinary CSF) is detected by the mouse CSF-1 RRA almost as sensitively as murine CSF-1. In addition, there was an absolute correlation between CSF-1 levels determined by murine CSF-1 RRA and those determined by a human CSF-1 RIA for a variety of human CSF-1 sources. The murine CSF-1 RRA is a sensitive (sensitivity 5 units or 1.0 femtomole of CSF-1 protein), rapid, and highly specific assay for CSF-1 in both murine and human sources.

Peritoneal exudate mononuclear phagocyte colony-forming cells: their proliferative state in vivo and sensitivity to cytotoxic agents

We investigated the proliferative state of peritoneal exudate macrophage colony-forming cells (PE-CFC) by exposing them to [3H]thymidine with a high specific activity in vitro and by administering cytosine arabinoside and methotrexate in vivo. Since [3H]TdR had no appreciable killing effect on PE-CFC and since the drug treatment caused no reduction in the appearance of PE-CFC, we concluded that the majority of PE-CFC, if not all, are not in active cell cycle. The production of PE-CFC was, however, suppressed by the administration of nitrogen mustard, cyclophosphamide, BCNU and vinlastine.

Stimulation of macrophage plasminogen activator activity by colony-stimulating factors

Colony-stimulating factors (CSFs) stimulate granulocyte-macrophage praoduction from single hemopoietic progenitor cells. Various preparations of purified CSFs of two different subclasses have been shown here to stimulate a plasminogen-dependent fibrinolytic (plasminogen activator) activity from resident and starch-induced mouse peritoneal macrophages. Lymphocyte supernatants also stimulate macrophage plasminogen activator (PA) activity. Since they contain colony stimulating activity, it is possible that one or more subclasses of CSF in these supernatants is responsible for this effect. Since both colony-stimulating and macrophage growth activities have been detected at inflammatory sites, these findings could reflect a role for CSF in inflammatory processes.

Limitation of macrophage production in long-term marrow cultures containing prostaglandin E

Addition of prostaglandin E2 (PGE2) significantly altered the cellular composition of murine long-term bone marrow cultures. After 4--5 weeks of culture, increased cellularity in the suspension phase was observed in all cultures containing prostaglandin. These suspension cells contained markedly higher proportions of differentiated neutrophils than did cells cultured in the absence of PGE2. Granulocyte-macrophage progenitor cell levels in the suspension layer were increased 3--20 fold after five weeks in prostaglandin-containing cultures compared with control cultures. Fewer cells comprised the adherent layer in cultures containing prostaglandin. The number of macrophages in this layer was reduced 3--8 fold in these cultures compared with control cultures, while the number of granulocytes was increased 2--3 fold. The progenitor cells biased toward macrophage development were selectively inhibited in the cultures with PGE2. There was no significant effect of PGE2 on pluripotent stem cell levels or on the longevity of the cultures. It is concluded that excessive monopoiesis in bone marrow may be limited by PGE2 without influencing either stem cell maintenance or the development of other marrow-derived cell types.

Specific interaction of murine colony-stimulating factor with mononuclear phagocytic cells

L-cell colony-stimulating factor (CSF) is identical to macrophage growth factor and stimulates macrophage proliferation (Stanley et al., 1976, J. Exp. Med. 143: 631-647). The nature of the interaction of iodinated L-cell CSF (125I-CSF) with murine peritoneal exudate macrophages was studied. On incubation with 10 pM 125I-CSF at 0 degrees C, cellular binding of 125I-CSF reaches a stable maximum within 15 h. This is in contrast to the association behavior at higher temperatures. At 37 degrees C, cell-associated 125I-CSF levels reach, within 45 min, an unstable maximum which is up to 10-fold less than that occurring under the same conditions at 0 degrees C. At 0 degrees C, binding is saturated (approximately 5 X 10(4) sites/cell) at CSF concentrations of 1 nM. A comparison of binding and competition experiments indicates that iodinated L-cell CSF binds as effectively as L-cell CSF and that human urinary CSF and L-cell CSF equipotently compete for 125I-CSF binding. Specificity of the CSF-binding site is demonstrated by the failure of other known growth factors and hormones to compete for 125I-CSF binding. These studies and other findings suggest that 125I-CSF binding is restricted to macrophages and their precursors and to macrophage cell lines and that the binding site(s) is the receptor mediating the biological action of this CSF.

Secretion and partial degradation of granulocyte-macrophage colony-stimulating factor (GM-CSF) of mouse L-P3 cells

Secretion of a granulocyte-macrophage colony-stimulating factor (GM-CSF) was accomplished by L-P3 cells in culture with a serum-free medium. Cell proliferation per se was not requisite for the production of GM-CSF; the cells continued secreting GM-CSF even after their growth had been suspended. The amount of GM-CSF accumulated in the conditioned medium was reasonably accounted by the daily rate of production, and the addition of a proteinase inhibitor such as leupeptin and pepstatin did not result in greater accumulation of GM-CSF in the culture. It is thus postulated that there is no significant proteolytic inactivation of the secreted GM-CSF in the culture. However, when partially purified GM-CSF preparation was chromatographed on a gel-filtration column in the presence of 0.1% Triton X-100, a derivative of the GM-CSF was yielded which had been diminished in the molecular weight and altered in the isoelectric point. On the other hand, when leupeptin was included in the solution during production and isolation of the factor, the yielded GM-CSF did not manifest such a detergent-induced transformation and maintained its isoelectric point at pH 3.5. It is thus assumed that, in the presence of the detergent, GM-CSF suffers deterioration by an endogenous proteinase and releases a sialoglycopeptide fragment without loosing its colony-stimulating activity.

The regulation of haemopoiesis in long-term bone marrow cultures: I. role of L-cell CSF

The effects of L-cell conditioned medium which contains granulocyte/macrophage colony stimulating factor (CSF); of highly purified L-cell CSF; and the antiserum directed against L-cell CSF, have been investigated in long-term murine bone marrow cultures. Treatment of cultures with CSF containing conditioned medium led to a rapid decline in haemopoiesis. However, this inhibition of in vitro haemopoiesis is probably caused by materials other than CSF, since the addition of highly purified L-cell CSF had no appreciable effect upon long-term haemopoietic cell proliferation or differentiation. Furthermore, the inhibitory activity of L-cell conditioned medium was not abrogated following neutralization of the CSF activity by CSF antiserum. The direct addition of CSF antiserum did not inhibit granulocyte or macrophage formation. These results suggest that long-term cultures of murine marrow cells may show extensive interactions with stromal cells which are not influenced by exogenous stimulatory or inhibitory factors.

The effect of mouse lung granulocyte-macrophage colony-stimulating factor and other colony-stimulating activities on the proliferation and differentiation of murine bone marrow cells in long-term cultures

The roles of colony-stimulating factors in long-term bone marrow cultures were studied and compared. After single additions of high concentrations of unpurified colony-stimulating activities to the cultures, rapid deterioration of the cultures was observed. This appears to result from contaminants in the stimulatory preparations. Cultures to which one purified colony-stimulating factor (csf) from endotoxin mouse lung-conditioned medium was added did not run down ten weeks after addition and were found to be the same as the controls. The deterioration of the cultures to which unpurified stimulators were added could not be accounted for by accelerated granulopoiesis leading to subsequent exhaustion of the cultures. The inability of purified CSF to affect the cellularity of the suspension cells did not result from instability or masking of the activity in the cultures, nor did CSF preferentially stimulate the cells within the adherent layer. The suspension cells responded to purified CSF after separation from the adherent cells. The data suggest that if CSFs are marrow stimulators, their effects in turn may be stringently regulated within the marrow.