Lipopolysaccharide inhibits the binding of colony-stimulating factor (CSF-1) to murine peritoneal exudate macrophages

These studies demonstrate the potent effect of bacterial endotoxin (LPS) on the inhibition of iodinated colony-stimulating factor- (125I-CSF-1) binding by murine peritoneal exudate macrophages (PEM) from C3H/An and C57BL/6 mice. As small an amount as 0.1 ng/ml LPS is sufficient to cause a significant inhibitory effect; this effect is temperature-, time- and concentration-dependent. LPS, however, causes minimal or no inhibition of 125I-CSF-1-binding by PEM from LPS-resistant C3H/HeJ mice. Inhibition of 125I-CSF-1-binding does not appear to be a result of a direct occupancy by LPS of CSF-1 receptors present on the cell membrane and is most likely due to a progressive loss of available CSF-1-binding sites. The effect can be neutralized by the addition of the antibiotic polymyxin B, which binds to the lipid A portion of LPS. The action of LPS on PEM is transient; treated cells recover their 125I-CSF-1-binding activity whether or not LPS is later removed. The restoration of 125I-CSF-1-binding activity can be blocked completely by the addition of cyclohexamide. These findings suggest the rapid, LPS-induced disappearance of CSF-1 receptors from the cell surface may be related to the activation of macrophages by LPS.     

Tumor-promoting phorbol esters inhibit the binding of colony-stimulating factor (CSF-1) to murine peritoneal exudate macrophages

L-cell colony-stimulating factor (CSF-1) is a sialoglycoprotein of molecular weight 70,000 daltons that specifically stimulates macrophage colony formation by single committed cells from normal mouse bone marrow and by various classes of more differentiated tissue-derived mononuclear phagocyte colony-forming cells (Stanley et al., 1978). CSF-1 interacts with target cells by direct and specific binding to membrane receptors (CSF-1 receptors) that are present only on cells of the mononuclear phagocyte series and their precursors. We studied the effect of tumor-promoting phorbol esters on the binding of 125I-labeled CSF-1 (125I-CSF-1) to murine peritoneal exudate macrophages (PEM). Biologically active TPA (12-O-tetradecanoyl phorbol-13-acetate) inhibits the binding of 125I-CSF-1 to its receptor on PEM. This inhibition exhibits temperature, time, and concentration dependence. At 37 degrees C, maximum inhibition occurred at about 10(-7) M; inhibition was 50% at 5 X 10(-9) M. At 0 degrees C, the inhibitory activity of TPA is diminished. The action of TPA on PEM is transient. Treated cells recover their 125I-CSF-1-binding activity whether TPA is later removed or not. The process of recovering CSF-1-binding activity is completely blocked by the addition of cycloheximide. When several phorbol derivatives were tested for their inhibitory activities, only biologically active phorbol esters were found to possess such activities. Furthermore, the inhibitory activities of various phorbol esters are proportional to their tumor-promoting activities. Inhibition appears to be due to a reduction in the total number of available CSF-1 receptors rather than a decrease in receptor affinity.     

Erythropoietin causes down regulation of colony-stimulating factor (CSF- 1) receptors on peritoneal exudate macrophages of the mouse

We have shown that erythropoietin (epo), the primary regulator of erythrocyte formation, diminished the binding to peritoneal exudate macrophages (PEM) of the principal macrophage growth regulator, colony- stimulating factor (CSF-1). The effect of epo on 125I-CSF-1 binding was dose-dependent; at a concentration of 1-2 U of epo/ml (10(-10) M), CSF- 1 binding was almost completely suppressed. Erythropoietin did not compete with CSF-1 for occupancy of the latter's receptors. The effect of epo on CSF-1 binding occurred at 37 degrees C but not at 2 degrees C, and during the continuous exposure of PEM to epo at 37 degrees C we found that CSF-1 binding reached a nadir at 1 h and recovered to pre- exposure levels in 7 h. Our novel results are consistent with the notion that specific receptors for epo exist on the cell surface of PEM and that binding of epo sets in motion a series of cellular events resulting in the internalization of CSF-1 receptors. Thus epo causes down regulation of CSF-1 receptors on PEM. We have previously shown that epo causes suppression of CSF-induced granulocyte-macrophage colony formation by mouse bone marrow cells. The results we present here provide a possible mechanism for these results.     

Role of phorbol ester receptors in the 12-0-tetradecanoyl-phorbol-13-acetate (TPA)-induced down-regulation of colony-stimulating factor (CSF-1) binding to murine peritoneal exudate macrophages

Treatment of murine peritoneal exudate macrophages (PEM) by tumor-promoting phorbol esters (TPA) results in a rapid loss of binding activity to radioactive-labeled colony-stimulating factor ([125I]-CSF-1) on the cell surface. The inhibitory effect of TPA on PEM is transient; treated cells recover full [125I]-CSF-1 binding activity in less than 6 hr at 37 degrees C either in the presence or after the removal of added TPA. The role of phorbol ester receptors in the induction of [125I]-CSF-1 binding inhibition was studied. The biologically active ligand [3H]-phorbol 12,13-dibutyrate ([3H]-PDBu) bound specifically to cultured murine PEM. At 0 degree C, stable and equilibrium binding occurred after 2-3 hr. Scatchard analysis revealed linear plots with a dissociation constant and receptor number per cell of 20.9 nM and 3.9 X 10(5)/cell, respectively. Treatment of PEM with biologically active phorbol esters at 37 degrees C rapidly inhibited the binding activity of [3H]-PDBu on cell surface (down-regulation) and rendered these cells refractory to the TPA-induced [125I]-CSF-1 binding inhibition by the subsequent TPA treatment. The inhibition of phorbol ester binding activity on TPA-treated PEM is caused by a reduction in the total number of available phorbol ester receptors rather than by a decrease in receptor affinity as judged by Scatchard analysis. The disappearance of [3H]-PDBu binding activity is reversible and transient. However, unlike CSF-1 receptors the restoration of phorbol ester receptors on TPA-treated PEM is a very slow process; a prolonged incubation of up to 72 hr after the removal of TPA was required for PEM to regain fully its [3H]-PDBu binding activity. Furthermore, the degree of TPA-induced CSF-1-receptor down-regulation is closely associated with the number of available phorbol ester receptors present on PEM at the time of treatment. Thus, the refractoriness to TPA diminished as the phorbol ester receptors on PEM recovered. A 72-hr incubation time at 37 degrees C was needed for PEM to lose their refractoriness and again become fully sensitive to TPA-induced CSF-1-receptor down-regulation. This study provides evidence that the loss of CSF-1-receptors induced by TPA treatment requires the presence of phorbol ester receptors and proceeds presumably via a co-internalization of both CSF-1 and phorbol ester receptors; the refractoriness to TPA is thereby induced by a transient loss of available phorbol ester receptors.     

Modulation of granulocyte colony-stimulating factor receptors on murine peritoneal exudate macrophages by tumor necrosis factor-alpha.

Modulation of granulocyte CSF (G-CSF) receptors on murine peritoneal exudate macrophages (PEM) by various cytokines was investigated. At 4 degrees C, 125I-G-CSF receptor binding on PEM reached a plateau after 6 h and was specifically competed by unlabeled human rG-CSF but not by other cytokines, including human rG-CSF-1, murine recombinant granulocyte-macrophage CSF, murine rIFN-gamma, human rIL-1 beta, and murine rTNF-alpha. 125I-G-CSF bound to PEM has a half-life of 30 min at 37 degrees C. Preincubation of PEM with murine rTNF, murine recombinant granulocyte-macrophage CSF, CSF-1, or G-CSF for 30 min at 37 degrees C resulted in partial reduction of 125I-G-CSF binding capacity, whereas IL-1 or IFN-gamma did not inhibit G-CSF binding. Further studies indicated that reduction of G-CSF binding caused by TNF was a dose- and time-dependent process and did not require FCS. The reduction was transient, and receptor binding was recovered by incubation at 37 degrees C for 8 h. The recovery of G-CSF binding was inhibited in the presence of cycloheximide. In addition, G-CSF binding studies suggested that the TNF-induced decrease in G-CSF binding to PEM was probably due to a reduction in receptor number rather than receptor affinity. Modulation of G-CSFR by TNF was also observed on nonelicited macrophages from various strains of mice. Our results demonstrate a physiologic response of G-CSFR on macrophages that is modulated by TNF. This phenomenon may play an important, as yet unknown, role in the macrophage inflammatory response.     

Binding, internalization and degradation of colony-stimulating factor by peritoneal exudate macrophages

Iodinated colony-stimulating factor produced by L-cells (125I-CSF-1) binds specifically to murine peritoneal exudate macrophages. At 37 degrees C, the cell-bound 125I-CSF-1 was internalized and degraded very rapidly, with the appearance of radioactive iodotyrosine in the medium. At 0 degree C, the cell-bound 125I-CSF-1 was not internalized and degraded, nor did it dissociate from the membrane. The internalization and degradation at 37 degrees C could be blocked or reduced by the presence of phenylglyoxal, methylamine and NH4Cl. The chemical nature of the CSF-1 binding site is polypeptide as judged by its sensitivity to trypsin treatment. After the binding and degradation of unlabeled CSF-1, the exudate cells were no longer able to rebind freshly added 125I-CSF-1, indicating the removal of CSF-1 binding site. The binding capacity of these cells, however, could be restored by prolonged incubation at 37 degrees C but not at 0 degrees C in culture medium containing fetal calf serum.     

Binding, internalization and degradation of colony-stimulating factor by peritoneal exudate macrophages

Iodinated colony-stimulating factor produced by L-cells (¹²⁵I-CSF-1) binds specifically to murine peritoneal exudate macrophages. At 37°C, the cell-bound ¹²⁵I-CSF-1 was internalized and degraded very rapidly, with the appearance of radioactive iodotyrosine in the medium. At 0°C, the cell-bound ¹²⁵I-CSF-1 was not internalized and degraded, nor did it dissociate from the membrane. The internalization and degradation at 37°C could be blocked or reduced by the presence of phenylglyoxal, methylamine and NH₄Cl. The chemical nature of the CSF-1 binding site is polypeptide as judged by its sensitivity to trypsin treatment. After the binding and degradation of unlabeled CSF-1, the exudate cells were no longer able to rebind freshly added ¹²⁵I-CSF-1, indicating the removal of CSF-1 binding site. The binding capacity of these cells, however, could be restored by prolonged incubation at 37°C but not at 0°C in culture medium containing fetal calf serum.     

Up-regulation of granulocyte-macrophage colony-stimulating factor (GM-CSF) receptors in murine peritoneal exudate macrophages by both GM-CSF and IL-3.

Murine peritoneal exudate macrophages (PEM) display multiple CSF receptors. In this study, the expression of granulocyte-macrophage (GM)-CSF receptors in PEM was studied. PEM displayed over 5000 single type, high affinity GM-CSF receptors/cell with a Kd = 38 to 42 pM and an apparent molecular mass of 86,000 Da. Treatment of PEM with low, but not high, concentrations of recombinant murine (rMu) GM-CSF continuously for 24 h resulted in a marked up-regulation of GM-CSF receptors in PEM. A similar up-regulation of GM-CSF receptors also was detected in PEM cultures treated with rMuIL-3 (1-100 ng/ml) for 24 h or longer, regardless the doses of rMuIL-3 added in this case. Scatchard analysis of equilibrium binding showed that the enhanced binding activities in both cases were due to an increase in total number of GM-CSF receptors rather than changes in receptor affinity. Contrariwise, treatment with recombinant human macrophage-CSF (greater than 100-1000 ng/ml) partially inhibited the expression of GM-CSF receptors in PEM. Removal of rMuGM-CSF from culture medium 24 h after treatment led to a further up-regulation of GM-CSF receptors over a 4 to 24-h period, depending on the doses of initial treatment. On the other hand, removal of rMuIL-3 from culture medium after prolonged treatment did not result in further increase in GM-CSF receptors. The protein synthesis inhibitor cycloheximide abrogated GM-CSF receptor up-regulation induced by both rMuIL-3 and rMuGM-CSF, whereas actinomycin D inhibited only the second (8-24 h) phase of GM-CSF receptor up-regulation induced by exposure to high concentrations rMuGM-CSF (10 ng/ml). These findings suggest that rMuGM-CSF and rMuIL-3 up-regulate GM-CSF receptors in PEM in part through similar or identical metabolic pathways and provide further evidence of a close linkage between IL-3 and GM-CSF receptors.     

Interaction of murine colony-stimulating factor (CSF-1) with alveolar mononuclear phagocytes

Colony-stimulating factor (CSF-1) was purified from serum-free L-cell-conditioned medium (LCM) and iodinated so that we could study its interaction with murine alveolar macrophages. At 0 °C, the binding of ¹²⁵ICSF-1 to alveolar macrophages reached a stable maximum within 16 h. Under this condition, the binding of ¹²⁵ICSF-1 at various concentrations was saturated at about 3 ng/ml. The binding sites of ¹²⁵ICSF-1 were sensitive to trypsin but not to DNase or RNase treatment. At 37 °C, the trypsin-treated cells regenerated more than 90% of their original binding sites within 12 h. Whereas more than 97% of these alveolar macrophages were phagocytic and esterase-positive, autoradiographic studies showed that only 10–31 % of them were capable of binding to ¹²⁵ICSF-1. These results indicate that the frequencies of CSF-1-binding cells and alveolar macrophage colony-forming cells (AL-CFC) are closely correlated, but no causal relationship has been established.     

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.     

Interleukin 3 (IL 3) regulates the in vitro proliferation of both blood monocytes and peritoneal exudate macrophages: synergism between a macrophage lineage-specific colony-stimulating factor (CSF-1) and IL 3

The effect of interleukin 3 (IL 3) on regulation of macrophage proliferation was examined. Although IL 3 alone stimulates the colony formation in bone marrow cells, it fails to stimulate the colony formation by both peritoneal exudate macrophages (PEM) and blood monocytes. However, IL 3 greatly enhances the proliferative capacity of both PEM and monocytes in responding to suboptimal concentrations of CSF-1. At supraoptimal concentrations of CSF-1, IL 3 did not increase the number of colonies, but greatly increased colony size. Kinetic studies showed that IL 3 enhances CSF-1-induced macrophage proliferation by shortening the cell doubling time. Monocytes were more sensitive to the action of IL 3 and possessed higher proliferative potential than PEM. Binding studies with radioactive labeled CSF-1 (125I-CSF-1) showed that IL 3 treatment induced an increased expression of CSF-1 receptor activity by PEM which appears to be a result of increased number of available receptor sites. The effect of IL 3 on the expression of receptor activity is both dose- and time-dependent. IL 3 also augments the rate of receptor-mediated CSF-1 endocytosis by PEM which appears to be a direct result of increased expression of CSF-1 binding sites. These results demonstrate that, in addition to stimulating the growth and differentiation of several blood cell lineages by hemopoietic stem cells, IL 3 also possesses the ability to modulate CSF-1 receptors, thereby affecting proliferation of more mature blood monocytes and tissue-derived macrophages.     

Characterization of deglycosylated human urinary colony-stimulating factor (CSF-1)

1. Isolation of CSF-1 from human urine was performed through five purification steps. These include concentration by dialysis, silica gel absorption, hydrophobic chromatography and phenyl-Sepharose CL-6B, Fast Protein Liquid Chromatography (FPLC) and finally preparative electrophoresis on polyacrylamide gels. These methods have been reported in a previous paper (Tao et al., 1987). 2. The isolated CSF-1 which exhibits a one band pattern on SDS-PAGE under non-reducing conditions after Coomassie Blue and silver stainings. CSF-1 was purified 100,000-fold and has a specific activity of 2.16 x 10(7) units/mg protein. Its apparent Mr is 57,000 with an isoelectric point pI = 5.8-6.0 CSF-1 is a glycoprotein with 40% of carbohydrate (w/w). 3. An almost complete removal of the carbohydrate moiety from CSF-1 was obtained after treatment with trifluoromethanesulfonic (TFMS) acid followed by gel filtration on Sephadex G-25 (Fine). The deglycosylated (DG) CSF-1 possesses an apparent Mr of 38,000 and an isoelectric point, pI: 6.2 as compared to native-CSF-1 (N-CSF-1), Mr = 57,000 and pI = 5.8 respectively. 4. The TFMS treatment did not alter the activities of CSF-1 as shown by biological assay and receptor binding assay. The thermostability experiment revealed that DG-CSF-1 was less stable than N-CSF-1. The circular dichroism spectra (CD) of N-CSF-1 and DG-CSF-1 were different. 5. The features of interaction of iodinated-N-CSF-1 and iodinated-DG-CSF-1 with single cell suspensions from human peritoneal macrophage were studied. The binding activity of peritoneal macrophage was the highest among all cells examined.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stimulatory effects of purified macrophage colony-stimulating factor on murine resident peritoneal macrophages

A purified preparation of macrophage colony-stimulating factor (M-CSF) free of interferon and endotoxin activity was studied for its effects on resident murine peritoneal macrophages. M-CSF was found to induce profound morphologic alterations in resident macrophages. These changes included a marked increase in cell size, membrane ruffling, and cytoplasmic vacuolization. Further, after 72 hr of incubation with 1000 U/ml of M-CSF, there were significant increases in macrophage DNA synthesis as measured by autoradiography (P less than 0.001), and in macrophage monolayer protein content (P less than 0.01). None of these changes was seen in control macrophages or those exposed to recombinant interferon-gamma (IFN). Low activity levels of the ectoenzymes 5'-nucleotidase (5'NTD) and alkaline phosphodiesterase I (APD) have been associated with certain macrophage functions, particularly the expression of tumor cytotoxicity. Macrophage monolayers exposed to M-CSF demonstrated an unaltered level of 5'NTD activity from controls and a significantly increased level of APD activity (P less than 0.01) and did not demonstrate an increased ability to kill tumor cells, as measured by the 51Cr-release assay. On the other hand, IFN caused significant decreases in both 5'NTD (P less than 0.05) and APD (P less than 0.01) and also induced marked tumoricidal activity in macrophage monolayers. These results indicate that purified M-CSF induces highly specific alterations in the functional activity and morphologic appearance of resident macrophages and these changes are distinct from those induced by IFN.     

Recombinant granulocyte-macrophage colony-stimulating factor increases adenylate cyclase activity in murine peritoneal macrophages

Granulocyte-macrophage colony stimulating factor (GM-CSF) is a pleiotrophic cytokine which stimulates the function and proliferation of macrophage populations. Although the effects of GM-CSF are diverse and GM-CSF has entered into clinical trials, relatively little is known about signal transduction pathways utilized by GM-CSF. In view of previous studies which have suggested that some of the effects of GM-CSF on monocyte-macrophages can be mimicked by agents which increase intracellular cAMP, we investigated the effect of rGM-CSF on adenylate cyclase (AC) activity in murine peritoneal macrophages. Adenylate cyclase activity was quantitated in macrophage membrane preparations and in intact cells. In seven separate experiments, GM-CSF (50 U/ml) increased AC activity by 61(6)% relative to macrophages treated with carrier medium alone. A dose-dependent increase in AC activity was observed (10 to 100 U/ml) which peaked within 1 to 5 min after the addition of GM-CSF and returned to basal levels by 10 to 20 min. Lineweaver-Burk analysis revealed that the Vmax of macrophage AC was increased from 0.40 to 0.52 pmoles cAMP/min by GM-CSF but the Km was unchanged. Intracellular cAMP was increased by GM-CSF to 129(27)% of control values by 1 min of treatment (n = 6). Under similar experimental conditions, GM-CSF did not increase the activity of PK C (n = 14) or phospholipase A2 (n = 3) in peritoneal macrophages. These data show that macrophage adenylate cyclase activity is rapidly stimulated by GM-CSF. Moreover, these findings support further study of the role of cAMP in transmitting the intracellular signals initiated by GM-CSF in tissue macrophages.     

Response of resident murine peritoneal macrophages to in vivo administration of granulocyte-macrophage colony-stimulating factor

The effect of s.c. inoculation of purified recombinant derived granulocyte-macrophage (GM)-CSF on resident murine peritoneal macrophages was assessed in this study. From 18 to 24 h after s.c. administration of GM-CSF to normal mice, the resident peritoneal macrophages were harvested and the levels of membrane-bound IL-1, FcR, Mac-1 cell-surface Ag, and class II MHC expression were assessed. Peritoneal cells from GM-CSF-inoculated mice had significantly greater levels of membrane-bound IL-1 than did control mice. In addition when resident peritoneal macrophages from normal mice were purified by adherence and grown in the presence of GM-CSF, they produced greater levels of both membrane-bound and secreted IL-1. The peritoneal cells from GM-CSF-inoculated mice did not differ from controls in the expression of class II MHC-encoded Ag. This observation was confirmed by the finding that GM-CSF was unable to induce class II MHC expression on P388D1 cells, whereas a secondary mixed leukocyte culture supernatant was. Peritoneal cells from GM-CSF-inoculated mice also exhibited greater levels of expression of FcR and the Mac-1 cell-surface Ag. This resulted in an increase in their ability to phagocytose opsonized SRBC in vitro.     

The effect of human recombinant macrophage colony-stimulating factor (CSF-1) on the murine mononuclear phagocyte system in vivo

Human recombinant macrophage CSF (CSF-1) was administered i.v. to mice. After four daily injections there was a dose-dependent increase in the responsiveness of bone marrow cells from the treated animals to CSF-1 in vitro. At the highest dose tested (20,000 U/day) there was a selective 10-fold increase in the circulating population of mature monocytes. CSF-1 treatment also increased the macrophage content of the liver and peritoneal cavity and caused splenomegaly. The macrophages isolated from the peritoneum of CSF-1-treated animals were larger and expressed higher levels of the macrophage-specific F4/80 Ag. These data demonstrate that CSF-1 can act as a circulating regulator of the mononuclear phagocyte system.     

Calcium transients during Fc receptor-mediated and nonspecific phagocytosis by murine peritoneal macrophages

Studies with populations of macrophages have produced conflicting results concerning the possibility that the concentration of intracellular ionized calcium [( Ca2+]i) may act as an important mediator for phagocytosis. Since asynchronous changes in [Ca2+]i in individual cells undergoing phagocytosis may be averaged to undetectability in population studies, we studied single adhering murine macrophages using fura-2 and our previously described digital imaging system. The proportion of macrophages phagocytosing IgG-coated latex beads was greater than for uncoated beads (percent phagocytosing cells: 71 +/- 7 vs. 27 +/- 7, P less than 0.01). Phagocytosis of IgG-coated and uncoated beads was always associated with a calcium transient that preceded the initiation of phagocytosis. No calcium transients were detected in cells that bound but did not phagocytose beads. Four major differences between Fc receptor-mediated and nonspecific phagocytosis were detected: (a) the duration of calcium transients was longer for nonspecific phagocytosis compared with Fc receptor-mediated phagocytosis (69.9 +/- 10.2 vs. 48.7 +/- 4.7 s, P less than 0.05) and the magnitude of calcium transients was less for nonspecific phagocytosis (178 +/- 43 vs. 349 +/- 53 nM, P less than 0.05); (b) removal of extracellular calcium abolished the calcium transients associated with nonspecific phagocytosis but had no effect on those associated with receptor-mediated phagocytosis; (c) in the absence of extracellular calcium, buffering intracellular calcium with a chelator reduced Fc receptor-mediated phagocytosis but had no additive inhibitory effect on nonspecific phagocytosis; and (d) inhibition of protein kinase C (PKC) with staurosporine inhibited nonspecific phagocytosis but had no effect on receptor-mediated phagocytosis. Our observations suggest that despite both types of phagocytosis being associated with intracellular calcium transients, the role played by intracellular calcium in the signaling pathways may differ for Fc receptor-mediated and nonspecific phagocytosis by elicited murine macrophages.     

Synthesis of membrane-bound colony-stimulating factor 1 (CSF-1) and downmodulation of CSF-1 receptors in NIH 3T3 cells transformed by cotransfection of the human CSF-1 and c-fms (CSF-1 receptor) genes.

NIH 3T3 cells cotransfected with the human c-fms proto-oncogene together with a 1.6-kilobase cDNA clone encoding a 256-amino-acid precursor of the human mononuclear phagocyte colony-stimulating factor CSF-1 (M-CSF) undergo transformation by an autocrine mechanism. The number of CSF-1 receptors on the surface of transformed cells was regulated by ligand-induced receptor degradation and was inversely proportional to the quantity of CSF-1 produced. A tyrosine-to-phenylalanine mutation at position 969 near the receptor carboxyl terminus potentiated its transforming efficiency in cells cotransfected by the CSF-1 gene but did not affect receptor downmodulation. CSF-1 was synthesized as an integral transmembrane glycoprotein that was rapidly dimerized through disulfide bonds. The homodimer was externalized at the cell surface, where it underwent proteolysis to yield the soluble growth factor. Trypsin treatment of viable cells cleaved the plasma membrane form of CSF-1 to molecules of a size indistinguishable from that of the extracellular growth factor, suggesting that trypsinlike proteases regulate the rate of CSF-1 release from transformed cells. The data raise the possibility that this form of membrane-bound CSF-1 might stimulate receptors on adjacent cells through direct cell-cell interactions.     

Uptake and destruction of 125I-CSF-1 by peritoneal exudate macrophages

The binding and uptake of the colony-stimulating factor CSF-1 by peritoneal exudate macrophages (PEM) from lipopolysaccharide insensitive C3H/HeJ mice was examined at 2 degrees C, and at 37 degrees C. At 2 degrees C, 125I-CSF-1 was bound irreversibly to the cell surface. At 37 degrees C, 90% of the cell surface associated 125I-CSF-1 was rapidly internalized and subsequently degraded and the remaining 10% dissociated as intact 125I-CSF-1. Thus classical equilibrium or steady state methods could not be used to quantitatively analyze ligand-cell interactions at either temperature, and alternative approaches were developed. At 2 degrees C, the equilibrium constant (Kd less than or equal to 10(-13) M) was derived from estimates of the rate constants for the binding (kon congruent to 8 x 10(5) M-1 s-1) and dissociation (koff less than or equal to 2 x 10(-7) s-1) reactions. At 37 degrees C, the processes of dissociation and internalization of bound ligand were kinetically competitive, and the data was formally treated as a system of competing first order reactions, yielding first order rate constants for dissociation, koff = 0.7 min-1 (t1/2 = 10 min) and internalization, kin = 0.07 min-1 (t 1/2 = 1 min). Approximately 15 min after internalization, low-molecular weight 125I-labeled degradation products began to appear in the medium. Release of this degraded 125I-CSF-1 was kinetically first order over three half-lives (Kd = 4.3 x 10(-2) min-1, t1/2 = 16 min). Thus CSF-1 binds to a single class of receptors on PEM, is internalized with a single rate limiting step, and is rapidly destroyed without segregation into more slowly degrading intracellular compartments.