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

Retrograde transport and steady-state distribution of 125I-nerve growth factor in rat sympathetic neurons in compartmented cultures

We have used compartmented cultures of rat sympathetic neurons to quantitatively examine the retrograde transport of 125I-nerve growth factor (NGF) supplied to distal axons and to characterize the cellular events that maintain steady-state levels of NGF in cell bodies. In cultures allowed to reach steady-state 125I-NGF transport, cell bodies contained only 5-30% of the total neuron-associated 125I-NGF, whereas 70-95% remained associated with the distal axons. This was true over an 8 pM to 1.5 nM 125I-NGF concentration range, indicating that saturation of high affinity receptors could not account for the large fraction of 125I-NGF remaining in axons. Dissociation assays indicated that 85% of 125I-NGF associated with distal axons was surface-bound. At steady-state, only 2-25% of the distal axon-associated 125I-NGF was retrogradely transported each hour, with higher transport rates associated with younger cultures and lower 125I-NGF concentrations. The velocity of 125I-NGF retrograde transport was estimated at 10-20 mm/hr. However, as in a previous report, almost no 125I-NGF transport was observed during the first hour after 125I-NGF administration, indicating a significant lag between receptor binding and loading onto the retrograde transport system. During 125I-NGF transport through axons spanning an intermediate compartment in five-compartment cultures, little or no 125I-NGF was degraded or released from the axons. After transport, 125I-NGF was degraded with a half-life of 3 hr. In summary, although some cellular events promoted NGF accumulation in cell bodies, distal axons represented by far the principal site of NGF-receptor interaction at steady-state as a result of a low retrograde transport rate.

Downregulation of colony-stimulating factor-1 (CSF-1) binding by CSF-1 in isolated osteoclasts

Colony-stimulating factor-1 (CSF-1), also called macrophage colony-stimulating factor, is the growth factor for the cells of the mononuclear phagocytic system. Furthermore, CSF-1 is essential in osteoclastogenesis and also affects mature osteoclasts. The receptor for CSF-1 was demonstrated on cells of the osteoclast lineage, with highest levels on the mature cells. This study investigated whether the binding of CSF-1 to isolated rat osteoclasts is modulated by the growth factor itself. Exposure of osteoclasts to CSF-1 for 1 hour virtually abolished binding of the growth factor. After removal of CSF-1, binding sites were restored within 4 hours. This recovery was blocked by cycloheximide, indicating the dependence on new protein synthesis for reexpression of receptors on the cell surface. The observed downregulation of CSF-1 binding sites might be a mechanism to control the effects of the growth factor on mature osteoclasts.

Binding, internalization and degradation of radio-iodinated interleukin 3 and granulocyte-macrophage colony stimulating factor by various hemopoietic cells

The proliferation and differentiation of hemopoietic committed progenitor cells depend on colony stimulating factors (CSF). However, isolated mouse granulocyte-macrophage progenitor cells can still undergo limited proliferation in serum-free cultures after CSF deprivation. To test whether this is due to an accumulated pool of internalized factor, we examined the binding, internalization and degradation of radiolabelled interleukin 3 (IL-3) and granulocyte-macrophage colony stimulating factor (GM-CSF) in various hemopoietic cells. We found 20,000 high affinity IL-3 receptors on cells of two IL-3-dependent hemopoietic cell lines, FDC-P1 and FDC-P2 (Kd = 85 and 129 pM). FDC-P1 cells, which also respond to GM-CSF, possess 600 high-affinity GM-CSF receptors (Kd = 64 pM). Cells of both lines internalize IL-3, but only FDC-P1 cells release degraded IL-3 at a rapid rate. Both cell lines have similar dose-response curves for IL-3 and survival kinetics after factor removal. All other cells tested behave like FDC-P1, suggesting that the metabolism of IL-3 by FDC-P2 is exceptional. Our study indicates that transient proliferation of committed progenitor cells in the absence of added factors is apparently not due to a stable pool of internalized CSF but merely represents an intrinsic capability of these cells.

Cellular processing of murine colony-stimulating factor (Multi-CSF, GM-CSF, G-CSF) receptors by normal hemopoietic cells and cell lines

The binding, internalization and degradation rates of three different murine colony-stimulating factors (Multi-CSF or interleukin-3, GM-CSF and G-CSF) and their receptor turnover rates were determined for normal bone marrow cells and a number of different cell lines at 37 degrees C. The kinetic parameters were extracted from a curve-fitting analysis of the approach to steady-state of surface-bound and internalized CSFs by methods described by Myers et al. (1987). The primary binding kinetic constants (association and dissociation) for each CSF on different cell types were similar, suggesting a single type of receptor for each CSF. In all cases, CSF binding induced a faster rate of internalization of occupied receptors than unoccupied receptors and resulted in significant accumulation of CSF inside the cell under steady-state conditions. The steady-state constant, determining the relationship between CSF concentration and receptor occupancy, indicated that, in all cases, more receptors were occupied at a given CSF concentration under steady-state conditions than would be under equilibrium conditions. Nevertheless, the data predicted that maximal biological effects of the CSFs were exerted at concentrations that did not result in full receptor occupancy. Comparison of the kinetic constants derived for the same CSF interacting with different types of cells or different CSFs interacting with the same cell type indicated that CSF and receptor processing resulted from a dynamic interplay of receptor-determined and cell-determined events. This resulted in a flexibility of the kinetic parameters that matched the variety of biological responses elicited by CSFs in different cell types.

Regulation of cell-surface receptors for hematopoietic differentiation-inducing protein MGI-2 on normal and leukemic myeloid cells

The normal myeloid hematopoietic regulatory proteins include 4 different growth-inducing proteins (IL-3, MGI-1GM = GM-CSF, MGI-1G = G-CSF, and MGI-1M = M-CSF = CSF-1). There is also another type of normal myeloid regulatory protein (MGI-2) with no MGI-1 (CSF or IL-3) activity, which can induce differentiation of normal myeloid precursors and certain clones of myeloid leukemic cells. Studies on the binding of MGI-2 to differentiation-competent (D+) and differentiation-defective (D-) clones of mouse myeloid leukemic cells and to normal cells indicate that: (1) D+ clones of myeloid leukemic cells had about 2,500 high-affinity surface receptors per cell, like mature normal myeloid cells, and the bound MGI-2 was rapidly internalized with its cell-surface receptors at 37 degrees C causing down-regulation of MGI-2 receptors in both the normal and leukemic cells; (2) in some D- clones, the number and internalization of MGI-2 receptors were similar to those of D+ clones whereas other D- clones had only 0-100 MGI-2 receptors per cell; (3) normal thymus and lymph-node lymphocytes and T lymphoma cells did not show detectable MGI-2 receptors; (4) there was an independent expression of receptors for MGI-2 and for the 4 myeloid growth-inducing proteins on different clones of myeloid leukemic cells; and (5) none of the 4 myeloid growth-inducing proteins IL-3, MGI-1GM, MGI-1G, or MGI-1M, inhibited binding of MGI-2 to its receptors. The cytotoxic proteins lymphotoxin and tumor necrosis factor did not induce differentiation of the mouse myeloid leukemic cells and also did not inhibit binding of MGI-2 to its receptors. These results show that the myeloid differentiation-inducing protein MGI-2 binds to cell-surface receptors that are different from the receptors for the 4 myeloid growth-inducing proteins and these cytotoxic proteins.

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.

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.

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.

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.