Opposing effects of dexamethasone on the clonal growth of granulocyte and macrophage progenitor cells and on the phagocytic capability of mononuclear phagocytes at different stages of differentiation

Dexamethasone, a synthetic glucocorticosteroid, was shown to modulate the colony-stimulating factor-dependent clonal growth of myeloid progenitor cells in semisolid agar cultures, enhancing the formation of granulocyte colonies (50–100%) and suppressing the formation of macrophage colonies (75–97%). Modulation of the pattern of myeloid colony formation by dexamethasone (12–125 nM) was brought about when the steroid was administered to 6-day cultures at the time of culture initiation and up to 72 hr later. Dexamethasone inhibited myeloid cell proliferation when administered to 5-day liquid cultures at culture initiation and up to 96 hr later. Dexamethasone (12–250 nM) also enhanced the phagocytic activity of bone marrow-derived mononuclear phagocytes toward heat-killed (HK) yeast cells (up to 100%) and IgG-coated sheep red blood cells (up to 60%). Enhancement of the phagocytic capability depended critically on the stage in culture at which dexamethasone was administered. Exposure to dexamethasone for 28 hr up to 96 hr of 96-hr cultures of bone marrow cells did not lead to a modulation of phagocytic activity of the developing mononuclear phagocytes. The presence of dexamethasone during the critical period of 96 hr to 120 hr after culture initiation led to an enhanced phagocytic capability, which was statistically significant already 12 hr after the administration of the glucocorticoid. Dexamethasone induced an enhanced phagocytic activity when administered at any time after culture initiation provided that it was in culture during this critical period. When added at 120 hr of culture, dexamethasone no longer enhanced the phagocytic capability of mononuclear phagocytes and when added later than 156 hr of culture suppressed it. Dexamethasone also suppressed (up to 68%) the phagocytic capability of resident and elicited peritoneal macrophages. The results suggest that glucocorticoids shift the balance of granulocyte vs. macrophage formation at early stages of precursor cell differentiation. Reduction in mononuclear phagocyte growth and enhancement of its phagocytic capability might reflect accelerated differentiation/maturation steps. The inhibitory effect of dexamethasone on macrophage formation and on the phagocytic capability of mature mononuclear phagocytes and peritoneal macrophages might be a relevant aspect of the in vivo immune suppression encountered after glucocorticoid administration.     

Formation of Mononuclear Phagocyte (Macrophage) Colonies by Mouse Spleen Cells in Liquid Culture

When spleen cells of the adult mouse were tested for the formation of mononuclear phagocyte (macrophage) colonies by the liquid culture technique with an incubation period of 7–8 days, about 100 macrophage colonies were produced from 1 × 10⁶ cells. The number of macrophage colonies appearing after 2 days of incubation was small, but thereafter increased progressively up to at least 8 days. In the later stages of incubation (after day 6) large colonies consisting of more than 100 cells appeared. Macrophage colonies in the early stages consisted almost solely of macrophages. On day 6 significant numbers of small round mononuclear cells with no detectable phagocytic activity were seen in the center of large colonies, and by day 8 marked crowding of these cells had occurred. The peripheral region of the large colonies consisted mainly of macrophages and the intermediate region of middle-sized round or slightly stretched cells with weak phagocytic activity. Approximately two-thirds of the colony-forming cells still remained after glass-adherent cells were removed from the spleen cells by passing over a glass-bead column. In cultures of glass-nonadherent cells macrophage colonies were not generated in the early stage. The number of colony-forming cells did not change significantly even after actively phagocytic cells were rigorously removed from the spleen cells. In addition, no macrophage colonies were generated in cultures of spleen cells treated with mitomycin C.     

Mononuclear macrophage (M-CFC) colony formation in semisolid media in the absence of exogenous GM-CSF

Human fetal bone marrow (FBM) cells were examined for the ability to form colonies in the absence of exogenous colony-stimulating factor (CSF) in double layer agar, methylcellulose (MC), and in agar-MC (agar underlayer, MC overlayer) culture systems. Without exogenous CSF, macrophage colonies (M-CFC) were formed in a combined culture of agar and MC. Aggregates of 5-40 cells were observed on day 7. Gradually, large compact colonies which survived for 10-12 weeks of cultivation, were formed. They were composed of mononuclear monocytes and multinucleated cells. M-CFC progenitors were nonadherent, but their progeny became adherent during differentiation within the colony. Colony formation was cell-dose-dependent. Depletion of monocytes increased the number of colonies in agar-MC cultures and stimulated the development of some macrophage colonies in MC. Survival of monocyte progenitors was not dependent on CSF. Neither was their proliferation nor partial differentiation in agar-MC cultures. CSF increased M-CFC colony efficiency, however, if it was present when cultures were initiated. Addition of CSF to M-CFC growing for 2-5 weeks in CSF-deprived medium stimulated monocytes proliferation and transformation into macrophages. Epithelioid cells, an increase in the number of giant multinucleated cells, and granulocyte multiplication were also observed. The absolute dependence of macrophage colony formation on CSF described by others might be a result of inadequate culture conditions due to agar rather than an intrinsic physiological requirement.     

Modulation of normal myelopoiesis invitro by retinoic acid

The effects of retinoic acid (RA) on the proliferation and differentiation of normal myeloid progenitor cells (CFU-C) were studied. In general, RA at 10^?10 to 10^?6 M enhanced primary myeloid colony formation in the presence of colony-stimulating factor(s). However, macrophage colony formation was strongly inhibited by RA. This may be related to the finding that RA is able to differentiate bipotential HL-60 cells into granulocytes but not into macrophages. Moreover, secondary colony formation was always suppressed by the addition of RA to the primary cultures. It means that self-renewal capacity of CFU-C was suppressed by RA. This finding suggests that normal myelopoiesis will be suppressed eventually by RA.     

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.     

Studies on colony formation in vitro by mouse bone marrow cells. I. Continuous cluster formation and relation of clusters to colonies

Colony formation in vitro by mouse bone marrow cells following stimulation by human urine was analysed over a 7-day incubation period. There was a linear increase with time in the number of cell aggregates (clusters) developing in such plates. Early in the incubation period all clusters were granulocytic although later macrophage clusters developed. Although most fully developed colonies were composed of macrophages, mapping and transfer studies showed that at least half of these had initially arisen early in the incubation period as granulocytic clusters.     

IL-6 is a differentiation factor for M1 and WEHI-3B myeloid leukemic cells

IL-6 has multiple biologic activities in different cell systems including both the ability to support cell proliferation and to induce differentiation. We reported previously the isolation and functional expression of a mouse IL-6 (mIL-6) cDNA clone derived from bone marrow stromal cells. In this paper, we show that mIL-6 is a potent inducer of terminal macrophage differentiation for a mouse myeloid leukemic cell line, M1. Addition of mIL-6 to cultures of M1 cells rapidly inhibits their proliferation and induces phagocytic activity and morphologic changes characteristic of mature macrophages. These phenotypic changes are accompanied at the molecular level by a decrease in proto-oncogene c-myc mRNA accumulation and increases in Fc gamma R, proto-oncogenes c-fos and c-fms (CSF-1R) mRNA expression. Furthermore, IL-6 enhances the expression of Fc gamma R and c-fms in differentiation-responsive D+, but not unresponsive D- sublines of mouse myelomonocytic leukemic WEHI-3B cells. Together with our previous observation that IL-6 stimulates colony formation by normal myeloid progenitors, these results strongly suggest an important regulatory role for IL-6 in myeloid cell growth and differentiation.     

Identification of a common signal associated with cellular proliferation stimulated by four haemopoietic growth factors in a highly enriched population of granulocyte/macrophage colony-forming cells.

We have prepared a population of bone marrow cells that is highly enriched in neutrophil/macrophage progenitor cells (GM-CFC). Four distinct haemopoietic growth factors can stimulate the formation of mature cells from this population, although the proportions of neutrophils and/or macrophages produced varied depending on the growth factor employed: interleukin 3 (IL-3) and granulocyte/macrophage colony-stimulating factor (GM-CSF) stimulated the formation of colonies containing both neutrophils and macrophages; macrophage colony-stimulating factor (M-CSF) produced predominantly macrophage colonies; and granulocyte colony-stimulating factor (G-CSF) promoted neutrophil colony formation. Combinations of these four growth factors did not lead to any additive or synergistic effect on the number of colonies produced in clonal soft agar assays, indicating the presence of a common set of cells responsive to all four haemopoietic growth factors. These enriched progenitor cells therefore represent an ideal population to study myeloid growth-factor-stimulated survival, proliferation and development. Using this population we have examined the molecular signalling mechanisms associated with progenitor cell proliferation. We have shown that modulation of cyclic AMP levels has no apparent role in GM-CFC proliferation, whereas phorbol esters and/or Ca2+ ionophore can stimulate DNA synthesis, indicating a possible role for protein kinase C activation and increased cytosolic Ca2+ levels in the proliferation of these cells. The lack of ability of all four myeloid growth factors to mobilize intracellular Ca2+ infers that these effects are not achieved via inositol lipid hydrolysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

1 alpha, 25-Dihydroxyvitamin D3 augments clonal growth of macrophages from rat bone marrow progenitor cells and modulates their function

1 alpha, 25-Dihydroxyvitamin D3 (1,25(OH)2D3) was shown to enhance (approximately 2 fold) the colony-stimulating factor-dependent clonal growth of macrophage colonies and clusters from rat bone marrow progenitor cells. The proliferative capacity of macrophage progenitors in liquid cultures was likewise augmented (2-3 fold). Mononuclear phagocytes (macrophages, for simplicity) developing in the presence of 1,25(OH)2D3 showed a reduced capacity of migration. 1,25(OH)2D3 administered at bone marrow culture initiation led to augmentation of the phagocytic capability of macrophages in four-day cultures and to its suppression in macrophages in seven-day cultures. The observed patterns of modulation of differentiation and function by 1,25(OH)2D3 differ from the patterns we found for mouse bone marrow cells. The results suggest that the differential response to hormones observed in different species may include responses to 1,25(OH)2D3.     

Origins of macrophage diversity: functional and phenotypic analysis of cloned populations of mouse splenic macrophages

Soft-agar colonies of mouse splenic macrophages were examined for surface and functional characteristics that might prove useful in studying the origin(s) of macrophage diversity. Flow cytoflurometric analysis revealed that essentially all cells in all of the colonies bore the Mac-1 and Mac-3 antigens. The colonies did not differ appreciably in their phagocytic activity or in their secretion of lysozyme, but did show different patterns of Mac-2 antigen expression. In most colonies, the cells expressed low levels of the antigen, and in the remainder they expressed a high or an intermediate level of Mac-2. The colonies also differed in their ability to present keyhole limpet hemocyanin (KLH) to an antigen-specific H-2-restricted T-cell hybridoma. About 6% of the colonies gave rise to subcultures with antigen-presenting activity. This presentation was always associated with subcultures containing a high proportion of Ia-bearing macrophages, but not all cultures with similarly high proportions of Ia-bearing cells presented KLH to the hybridoma. Indeed, the induction of Ia on all cells in all cultures increased the proportion of KLH-presenting subcultures only about twofold. The results show that not all splenic macrophages have the ability to process KLH and present it to a T-cell hybridoma. This suggests the presence of functionally specialized subpopulations of macrophages, possibly derived from distinct progenitors, in the spleens of mice.     

Effect of capsular polysaccharide of Klebsiella pneumoniae on the differentiation and functional capacity of macrophages cultured in vitro.

The effect of the capsular polysaccharide of Klebsiella pneumoniae (CPS-K) on the differentiation and functional capacity of macrophages cultured in vitro from various lymphoid tissues was investigated. In cultures of peritoneal cells, the number of macrophages did not change throughout incubation periods of from 1 hr to 3 days, and the addition of CPS-K had no affect. It appears therefore that CPS-K does not exhibit cytotoxic effects on macrophages. In cultures of spleen cells, only a small number of macrophages appeared within 1 hr, but the number of macrophages increased during further incubation. The addition of CPS-K to cultures of spleen cells at the start of incubation suppressed markedly the increase in the numbers of macrophage. This finding indicates that CPS-K blocks the process of the generation of macrophages, probably from their precursor cells in cultures of spleen cells. Only a small number of macrophages appeared in cultures of thymocytes or lymph node cells either with or without CPS-K. The phagocytic capacity of either peritoneal macrophages or macrophages generated in cultures of spleen cells was activated during incubation in vitro. Macrophages cultured in the presence of CPS-K for 24 hr or longer appeared to have an enhanced phagocytic activity, although the enhancement of their phagocytic activity by the addition of CPS-K was less marked in cultures of spleen cells than in those of peritoneal macrophages. Morphologically, macrophages in both cultures of peritoneal cells and spleen cells incubated in the presence of CPS-K for 4 days possessed much longer cytoplasmic processes than those incubated in the absence of CPS-K. From the present study, it appears that CPS-K exhibits dual effects on macrophage precursor cells and macrophages, a blocking effect on the differentiation from the former to the latter and an enhancing effect on the functional capacity of the latter.     

Role of granulocyte/macrophage colony-stimulating factor in the regulation of murine alveolar macrophage proliferation and differentiation

Granulocyte/macrophage (GM)-CSF is one of the hemopoietic growth factors that stimulates neutrophilic granulocyte and macrophage production by bone marrow progenitor cells. In this study, the effect of GM-CSF on the growth and differentiation of murine pulmonary alveolar macrophages (PAM) was investigated. In the presence of GM-CSF, normal murine PAM were induced to proliferate and develop into macrophage colonies with a dose-response curve similar to that of bone marrow GM colony-forming cells. PAM also responded to CSF-1, a lineage-restricted growth factor, but required much higher doses of CSF-1 and a longer incubation time for optimal colony formation. The proliferative response of PAM to CSF-1, however, was greatly enhanced by the concurrent addition of low doses of GM-CSF. In contrast, low doses of CSF-1 failed to potentiate the proliferative response of PAM to GM-CSF. Macrophages derived from GM-CSF cultures were rounder and less stretched and possessed less FcR-mediated phagocytic activity than cells produced in CSF-1 cultures. A study with hydrocortisone-induced monocytopenia showed that nearly one half of lung macrophages may be sustained by local proliferation of PAM without the continuous migration of blood monocytes. This study suggests that GM-CSF may play a major role in the production of PAM by two modes of action, 1) direct stimulation of cell proliferation and 2) enhancement of their responsiveness to CSF-1, thereby producing more mature and functionally competent macrophages.     

Hypothesis: the target cell of GM-CSF is a macrophage precursor capable to produce cells with the property to secrete a G-CSF like activity.

The induction of granulocyte and macrophage colony formation by the granulocyte-macrophage colony stimulating factor (GM-CSF) on bone marrow cells (BMC) was evaluated as a function of time in agar cultures. We found that while macrophage cell clusters were very abundant on the first two days of culture, granulocytic cell clusters did not appear until the third day. We also found that macrophage colonies were present from the fourth day of culture, while granulocyte colonies did not appear until the fifth day. When two day cell clusters were transferred to cultures with GM-CSF we observed that only macrophage-colonies developed. On the other hand, when four day clusters were transferred, both granulocyte and macrophage colony formation was obtained in a similar way as the one obtained when using GM-CSF with fresh BMC. Two day clusters did not respond to granulocyte colony stimulating factor (G-CSF) while fourth day clusters generated granulocytic colonies in a similar way as when G-CSF was used with fresh BMC. In order to test the hypothesis that granulocyte colony formation in these assays could be a result of the secretion of G-CSF by the macrophages previously induced by GM-CSF, lysates from macrophage colonies were used to induce colony formation on BMC. We observed that colonies, mainly granulocytic, were induced in a similar way as when G-CSF was used. Finally, the possibility that GM-CSF is just a macrophage inducer with the property to produce cells that secrete G-CSF is discussed.     

Alteration in cellular functions in mouse macrophages after exposure to 50 Hz magnetic fields

The aim of the present study is to investigate whether extremely low frequency electromagnetic fields (ELF-EMF) affect certain cellular functions and immunologic parameters of mouse macrophages. In this study, the influence of 50 Hz magnetic fields (MF) at 1.0 mT was investigated on the phagocytic activity and on the interleukin-1beta (IL-1beta) production in differentiated macrophages. MF-exposure led to an increased phagocytic activity after 45 min, shown as a 1.6-fold increased uptake of latex beads in MF-exposed cells compared to controls. We also demonstrate an increased IL-1beta release in macrophages after 24 h exposure (1.0 mT MF). Time-dependent IL-1beta formation was significantly increased already after 4 h and reached a maximum of 12.3-fold increase after 24 h compared to controls. Another aspect of this study was to examine the genotoxic capacity of 1.0 mT MF by analyzing the micronucleus (MN) formation in long-term (12, 24, and 48 h) exposed macrophages. Our data show no significant differences in MN formation or irregular mitotic activities in exposed cells. Furthermore, the effects of different flux densities (ranging from 0.05 up to 1.0 mT for 45 min) of 50 Hz MF was tested on free radical formation as an endpoint of cell activation in mouse macrophage precursor cells. All tested flux densities significantly stimulated the formation of free radicals. Here, we demonstrate the capacity of ELF-EMF to stimulate physiological cell functions in mouse macrophages shown by the significantly elevated phagocytic activity, free radical release, and IL-1beta production suggesting the cell activation capacity of ELF-EMF in the absence of any genotoxic effects.     

Chicken myeloid stem cells infected by retroviruses carrying the v-fps oncogene do not require exogenous growth factors to differentiate in vitro

To determine the function of c-fps in chicken macrophages and granulocytic cells we have infected chicken bone marrow cells with retroviruses containing the v-fps oncogene. Normal chicken macrophage progenitors, M-CFCs, give rise to macrophage colonies in semisolid cultures when macrophage colony stimulating factor (M-CSF) is added into the culture medium. Upon infection with v-fps bearing retroviruses, we observed that M-CFCs were induced to develop macrophage colonies in vitro without exogenous M-CSF. This activation results from a direct effect of v-fps on the M-CFCs. No leukemic transformation was observed in the infected colonies. By comparing the effects of several retroviruses, we showed that the induction of M-CFC development is specific to v-fps containing viruses and mediated by the v-fps protein. These observations support the hypothesis that the c-fps gene is involved in the control of proliferation and/or differentiation of myeloid cells.     

Plasticity of Human THP–1 Cell Phagocytic Activity during Macrophagic Differentiation

Studies of the role of macrophages in phagocytosis are of great theoretical and practical importance for understanding how these cells are involved in the organism’s defense response and in the development of various pathologies. Here we investigated phagocytic plasticity of THP–1 (acute monocytic human leukemia) cells at different stages (days 1, 3, and 7) of phorbol ester (PMA)–induced macrophage differentiation. Analysis of cytokine profiles showed that PMA at a concentration of 100 nM induced development of the proinflammatory macrophage population. The functional activity of macrophages was assessed on days 3 and 7 of differentiation using unlabeled latex beads and latex beads conjugated with ligands (gelatin, mannan, and IgG Fc fragment) that bind to the corresponding specific receptors. The general phagocytic activity increased significantly (1.5–2.0–fold) in the course of differentiation; phagocytosis occurred mostly through the Fc receptors, as shown previously for M1 macrophages. On day 7, the levels of phagocytosis of gelatin-and Fc–covered beads were high; however, the intensity of ingestion of mannan–conjugated beads via mannose receptors increased 2.5–3.0–fold as well, which indicated formation of cells with an alternative phenotype similar to that of M2 macrophages. Thus, the type and the plasticity of phagocytic activity at certain stages of macrophage differentiation can be associated with the formation of functionally mature morphological phenotype. This allows macrophages to exhibit their phagocytic potential in response to specific ligands. These data are of fundamental importance and can be used to develop therapeutic methods for correcting the M1/M2 macrophage ratio in an organism.     

Bone marrow precursors of nonobese diabetic mice develop into defective macrophage-like dendritic cells in vitro

The NOD mouse spontaneously develops autoimmune diabetes. Dendritic cells (DC) play a crucial role in the autoimmune response. Previous studies have reported a defective DC generation in vitro from the NOD mouse bone marrow (BM), but a deviated development of myeloid precursors into non-DC in response to GM-CSF was not considered. In this study, we demonstrate several abnormalities during myeloid differentiation of NOD BM precursors using GM-CSF in vitro. 1) We found reduced proliferation and increased cell death in NOD cultures, which explain the previously reported low yield of DC progeny in NOD. Cell yield in NOR cultures was normal. 2) In a detailed analysis GM-CSF-stimulated cultures, we observed in both NOD and NOR mice an increased frequency of macrophages, identified as CD11c(+)/MHCII(-) cells with typical macrophage morphology, phenotype, and acid phosphatase activity. This points to a preferential maturation of BM precursors into macrophages in mice with the NOD background. 3) The few CD11c(+)/MHCII(high) cells that we obtained from NOD and NOR cultures, which resembled prototypic mature DC, appeared to be defective in stimulating allogeneic T cells. These DC had also strong acid phosphatase activity and elevated expression of monocyte/macrophage markers. In conclusion, in this study we describe a deviated development of myeloid BM precursors of NOD and NOR mice into macrophages and macrophage-like DC in vitro. Potentially, these anomalies contribute to the dysfunctional regulation of tolerance in NOD mice yet are insufficient to induce autoimmune diabetes because they occurred partly in NOR mice.     

The Wellcome Foundation lecture, 1986. The molecular control of normal and leukaemic granulocytes and macrophages

The development of semisolid culture methods supporting the clonal proliferation and maturation of granulocytes and macrophages led to the discovery of a group of specific glycoproteins, the colony-stimulating factors (CSFs), whose function it is to control the proliferation and functional activity of granulocytes, macrophages and associated blood cells. The four known CSFs in the mouse and man have been purified and complementary DNAs (cDNAs) for each have been cloned. The injection of bacterially synthesized recombinant CSF into mice has demonstrated that these CSFs can function in vivo to regulate granulocyte and macrophage formation. A major physiological role played by these CSFs is to control resistance to invading microorganisms through mechanisms capable of extremely rapid activation. Because the CSFs are the only known proliferative factors for these cells, the CSFs are involved in the initiation and the emergence of myeloid leukaemia but, conversely, at least one of the CSFs, G-CSF, is able to suppress myeloid leukaemic populations because of the ability of the CSFs to initiate differentiation commitment in responding granulocytic and macrophage populations. The CSFs are promising agents for clinical use in the treatment of infections in patients with depressed granulocyte-macrophage formation and possibly in the management of some types of myeloid leukaemia.     

Complete replacement of serum in cultures of murine primitive erythroid and multipotential progenitor cells: absolute requirement for spleen conditioned medium

We describe a serum-free medium for the formation of erythropoietic bursts by murine bone marrow cells. Iscove's modified Dulbecco's medium supplemented with bovine serum albumin, iron-saturated transferrin, soybean phospholipids and cholesterol supported burst formation. The further addition of hemin increased burst numbers to above those obtained in serum-containing cultures. With or without hemin, a source of burst-promoting activity (BPA) (crude or partially purified spleen conditioned medium) and erythropoietin were essential. This system provides a sensitive assay for BPA. Of all colonies developing in these cultures, 16% were pure erythroid, 17% mixed erythroid/myeloid, 36% macrophage, 19% macrophage/basophil and macrophage/neutrophil, 9% basophil and 2% neutrophil.