Expression of interleukin 2 receptors on interleukin 3-dependent cell lines

Several mouse IL 3-dependent cell lines, IC2, LT4, FDC-P2, and PB-3C, derived from spleen or bone marrow cells were shown to express low affinity receptors for IL 2 (Kd; 0.5 to 8 X 10(-8) M). High affinity receptors for IL 2 were not detected on the IL 3-dependent cells within the experimental limitation of this study. The clones did not respond to IL 2 at all at the concentration as high as 25 micrograms/ml. The number of the receptors expressed on those clones was estimated to be 0.2 to 2 X 10(5)/cell, which is comparable with the number of those on IL 2-dependent T cell clones. Expression of IL 2 receptor was confirmed in mRNA levels for both IC2 and LT4 cells. A relatively low level expression of one (4.5 Kb) of four IL 2 receptor mRNA species was observed with those IL 3-dependent clones compared with IL 2-dependent T cells. It seems that these low affinity receptors may be expressed on IL 3-dependent cells that undergo differentiation or maturation in mast cell and some myeloid cell lineages.     

Expression of the functional erythropoietin receptors on interleukin 3-dependent murine cell lines

Two distinct hemopoietic growth factors, interleukin 3 (IL-3) and erythropoietin (EPO), support the growth and development of erythroid cells in a sequential manner in vitro. Stimulation of multipotential stem cells by IL-3 appears to develop committed erythroid progenitor cells that respond to EPO. When several murine IL-3-dependent cell lines were assayed for their ability to respond to EPO, the growth and survival of the three cell lines showing the profiles of either myeloid or mast cell lineage (IC-2, DA-1, FDC-P2) were stimulated by EPO in a dose-dependent fashion. To determine whether the biologic effects were mediated through the specific receptors for EPO, we performed binding experiments on these cells with radioiodinated EPO. All of these cells displayed significant levels of specific binding for EPO. Among a family of hemopoietic growth factors, only unlabeled EPO was able to compete for the binding of radioiodinated EPO to the cells. Analysis of the binding data revealed the existence of a single case of binding sites in extremely low abundance. IC-2 cells were used to study the effects of IL-3 on the regulation of expression of EPO receptors. It was demonstrated that a decrease in IL-3 concentration in the culture medium increased the responsiveness to EPO and the amount in specific binding of EPO as well. These results suggest that some IL-3-dependent cell lines have functional EPO receptors and their expression may be modulated by IL-3.     

Interleukin 2-dependent phosphorylation of interleukin 2 receptors and other T cell membrane proteins

The addition of IL 2 to Con A-activated splenic T cells induced the rapid and time-dependent phosphorylation of membrane proteins with m.w. of 115,000 to 105,000, 90,000, and 66,000, and to a lesser extent 55,000 to 58,000, 40,000, and 34,000. Immunoprecipitations conducted with an anti-IL 2 receptor antibody indicated that the murine IL 2 receptor (55,000 to 58,000) was included in the set of IL 2-dependent phosphoproteins. Phosphorylation of these same proteins was also seen after IL 2 treatment of PHA-activated T cells and of the IL 2-dependent line CTLL-2. Membrane phosphorylation was dependent on physiologically relevant IL 2 concentrations (0.2 to 1 ng/ml), and was detected as early as 1 min after IL 2 addition, with maximal levels of phosphorylation achieved by 15 min. In contrast to these observations, the pattern of cytoplasmic protein phosphorylation remained unchanged after IL 2 addition, although IL 2 did augment the level of preexisting cytoplasmic phosphorylation induced by lectin. The pattern of membrane protein phosphorylation induced by IL 2 also overlapped in part with that induced after stimulation of Con A-activated T cells with the phorbol ester PMA. IL 2-stimulated phosphorylation was inhibited by the addition of agents that both stimulate cyclic AMP-dependent protein kinases and block lymphocyte mitogenesis. No effect was seen upon addition of agents that enhance cyclic GMP-dependent protein kinases. These observations support a role for specific membrane as opposed to cytoplasmic protein phosphorylation in the regulation of lymphocyte growth by IL 2, and also suggest that protein kinase A, and perhaps protein kinase C, participate as regulators of the IL 2 signaling mechanism.     

Interleukin 3-dependent hematopoietic progenitor cell lines

Several biological phenotypes of growth factor-dependent cell lines have been described in recent years, including those with T lymphocyte, neutrophil granulocyte, basophil/mast cell, B lymphocyte, and multipotential stem cell properties. The growth factors for each cell lineage are a subject of intense study. Continuous mouse bone marrow cultures infected with RNA type C viruses (retroviruses) produce nonadherent hematopoietic cells over a longer duration than control cultures. Marrow cultures derived from strains with spontaneously induced ecotropic endogenous retrovirus demonstrate a greater longevity than those from strains with no replicating virus. Cultures infected with murine leukemia virus also generate a greater number, compared with controls, of cloned permanent suspension cell lines dependent for growth on a 41,000-dalton glycoprotein (interleukin 3 [IL 3]). Some are multipotential with capacity for differentiation to erythroid, neutrophil, eosinophil, and basophil/mast cell types. Other cloned IL 3-dependent cell lines are committed to a single pathway. Studies with Friend spleen focus-forming virus indicate that the first effect in the marrow culture is mediated through a subset of adherent hematopoietic stem cells. Bone marrow culture-derived IL 3-dependent cell lines provide a model with which to study the role of viral genes in the control of differentiation and self-renewal capacity of hematopoietic stem cells.     

Interleukin 1-dependent induction of both interleukin 2 secretion and interleukin 2 receptor expression by thymoma cells

The macrophage-derived product, interleukin 1 (IL 1) is thought to play an important regulatory role in the proliferation of T lymphocytes; however, its mechanism of action is unknown. We describe in this report a variant subline of EL4 thymoma cells (EL4-6.1) that displays a high degree of responsiveness to IL 1. We show that recombinant IL 1 can induce both the secretion of interleukin 2 (IL 2) and the expression of IL 2 receptors (IL 2-R) by these cells. EL4-6.1 cells do not constitutively secrete IL 2, nor do they express IL 2-R; but when cultured in the presence of recombinant IL 1, they secrete detectable amounts of IL 2 (5 to 15 U/ml). In the presence of either suboptimal levels of phorbol ester (PMA) or Ionomycin, the addition of IL 1 resulted in up to an 80-fold enhancement in the amount of IL 2 secreted. Stimulation with IL 1 alone or in combination with Ionomycin was unable to induce detectable IL 2-R expression by EL4-6.1 cells. However, in the presence of suboptimal concentrations of PMA, IL 1 induced expression of about 3000 high affinity (dissociation constant, Kd of 31 pM) and 50,000 low affinity (Kd of 2800 pM) IL 2-R. These IL 2-R were functional, based on their ability to rapidly internalize IL 2. This model system will allow a detailed analysis of the mechanisms involved in the regulation of the immune response by IL 1 and IL 2.     

Interleukin 2 rapidly stimulates synthesis and breakdown of polyphosphoinositides in interleukin 2-dependent, murine T-cell lines

Several T-cell functions are controlled by the regulatory peptide interleukin 2 (IL-2). Binding of IL-2 with specific receptors has been well documented, but the molecular mechanism by which IL-2/IL-2 receptor interaction is transduced is not known. We have found that treatment of IL-2-dependent T-cell lines with IL-2 is followed by a rapid stimulation of inositol phospholipid metabolism, as determined by isotopic methodology employing myo-[1,2-3H]inositol. Increased incorporation of the metabolic precursor into phosphatidylinositol and phosphatidylinositol 4-monophosphate, together with the appearance of radiolabeled phosphatidylinositol 4,5-bisphosphate, occurred within minutes of treatment with IL-2 of factor-dependent CT6 cells. Analysis of labeled water-soluble compounds from prelabeled cells indicated a rapid (within 1 min) stimulation of inositol phospholipid hydrolysis following IL-2 treatment. Increased recovery of [3H] inositol phosphates and appearance of [3H]inositol trisphosphate were observed after treatment with IL-2 of CT6 cells, as well as of a second IL-2-dependent cell line, CTB6. These findings suggests that inositol phospholipid-derived metabolites (i.e. diacylglycerol and inositol trisphosphate) may be part of the mechanism by which certain IL-2 signals are transduced.     

Transfer of functional EGF receptors to an IL3-dependent cell line

Epidermal growth factor (EGF) is a small protein that acts as a mitogen for various epidermal, epithelial, and fibroblastic cells that bear specific EGF receptors. The molecule that binds EGF is a 175-kD transmembrane protein, with an extracellular ligand binding domain and an intracellular domain that possesses tyrosine kinase activity, thought to be involved in the mitogenic signalling process. Here we have constructed a recombinant murine retrovirus that transduces a human cDNA encoding the 175-kD protein and used this retrovirus to infect BAF3, a murine, bone marrow-derived cell line, which is dependent on the haematopoietic factor interleukin-3 (IL3) for its growth in culture. The EGF receptors expressed in the infected cells exhibit two affinity states, as well as EGF-stimulated autophosphorylation. Furthermore, EGF can replace IL3 in supporting short-term proliferation of these cells. These data identify functional properties of the EGF receptor upon expression of the 175-kD EGF binding protein in a haemotopoietic cell that does not express endogenous receptors. They also suggest that gene transfer of growth factor receptors to heterologous cells may allow novel growth stimuli to be exploited.     

Induction of IL 2 responsiveness in a murine IL 3-dependent cell line

A mouse IL 3-dependent cell line, FD.C/1, can be induced to IL 2 growth responsiveness by culture in IL 2-conditioned culture medium. The IL 2-dependent cell lines derived by this procedure have been designated FD.C/2 cells. Once established, the FD.C/2 cells respond to human, rat, and mouse IL 2. When cultured with murine IL 3, FD.C/2 cells did not proliferate, appearing to accumulate in the G1 phase of the cell cycle. Other human and mouse lymphokines failed to stimulate FD.C/2 cell growth. The growth dependence of FD.C/2 cells on IL 2 could not be reversed to IL 3. Cell lines derived by these procedures could provide in vitro models for hemopoietic differentiative events.     

Interleukin 3 enhanced interleukin 2-dependent maturation of NK progenitor cells in bone marrow from mice with severe combined immunodeficiency

Human recombinant interleukin 2 (IL 2) and highly purified murine interleukin 3 (IL 3) were tested for their ability to generate NK activity in bone marrow cells from mice with severe combined immunodeficiency. IL 2 alone could dose dependently induce NK activity in marrow cells as determined by cytotoxicity against YAC-1 target cells. It was demonstrated that IL 3 had dual effects on the generation of NK activity in this culture system. The addition of IL 3 resulted in inhibition of NK cell activity seen at high concentrations of IL 2. In contrast, when IL 3 was added together with low concentrations of IL 2, the generation of NK cells as judged by cytotoxicity assay as well as the appearance of cells with NK phenotypes was markedly augmented. In some experiments, mice were treated with 5-fluorouracil (5-FU) to eliminate relatively differentiated NK precursors from bone marrow cells. It was noted that the residual immature marrow cells from 5-FU-treated mice showed little NK activity even after the culture with high concentrations of IL 2. Importantly, IL 3 could induce the generation of NK activity from 5-FU-treated marrow cells in the presence of IL 2. Kinetic studies indicated that NK activity was appreciably generated from 5-FU-treated marrow cells when preincubated with IL 3 at least for 12 hr and subsequently cultured with IL 2. The cells bearing IL 2 receptors appeared in 5-FU-treated marrow cells, even though cultured only with IL 3, which implied that IL 3 could support the development of very primitive NK cells from IL 2-unresponsive to IL 2-responsive states. These results suggested that IL 3 might play a crucial role for the IL 2-induced generation of NK cells in bone marrow through promoting the expression of IL 2R on NK progenitor cells.     

The induction of lymphokine synthesis and cell growth in IL 3-dependent cell lines using antigen-antibody complexes

Several IL 3-dependent murine bone marrow-derived cell lines can be stimulated to grow with antigen-antibody (Ag.Ab) complexes. The Ag.Ab complexes induced lymphokine gene expression and the synthesis of IL 2, GM-CSF, IL 3, and BSF-1 (IL 4). The lymphokines produced by these IL 3-dependent cells appeared to stimulate their own growth, as both IL 3 and BSF-1 (IL 4) stimulated the growth of IL 3-dependent cells. Ag.Ab complexes also stimulate the growth of primary cultures of bone marrow cells that have been previously activated with IL 3. Normal bone marrow, IL 2-, and GM-CSF-dependent bone marrow cell lines could bind Ag.Ab complexes, but binding did not result in the induction of lymphokine synthesis or cell growth. Hyperimmune serum from mice also stimulated lymphokine synthesis and cell growth in IL 3-dependent cells, and the stimulatory activity was removed by treatment with Staphylococcus aureus protein A, suggesting the presence of Ag.Ab complexes.     

Antigenic stimulation regulates the expression of IL 2 receptors in a cytolytic T lymphocyte clone

We have isolated and characterized an H-2Kb-specific CTL clone, B1.8, whose growth is strictly dependent on IL 2 and periodic exposure to stimulator cells. A single, brief encounter with antigen induces on resting B1.8 cells the expression of high-affinity IL 2 receptors, which is maintained for several days, thus allowing cells to undergo at least six rounds of division in the presence of affinity-purified IL 2. We show with the use of monoclonal anti-Lyt-2 or -H-2Kb antibodies, which block specific antigen recognition by B1.8 cells, that continuous antigenic stimulation is not required during this period of growth. After this time, B1.8 cells lose their ability to respond to IL 2 and revert to a resting state, a process that is reversed upon addition of fresh stimulator cells. The decline and subsequent arrest of cell growth correlates with a loss of IL 2 receptors; growth-arrested cells express a 10-fold lower number of receptors than actively growing cells.     

Internalization of interleukin 2 (IL-2) by high affinity IL-2 receptors is required for the growth of IL-2-dependent T cell lines

During the growth of interleukin 2 (IL-2)-dependent T cells IL-2 binding is followed by internalization of the complex between IL-2 and the high affinity IL-2 receptor (HA-IL-2R). The respective role of IL-2 binding to HA-IL-2R and internalization of the complex has been examined. Monoclonal antibody 7D4 (IgM) blocks IL-2-dependent T cell growth although it does not affect IL-2 binding to HA-IL-2R. We show here that 7D4 inhibits T cell growth by blocking IL-2 internalization by HA-IL-2R. In contrast, Fab fragments prepared from 7D4 neither block IL-2 internalization nor inhibit T cell growth. Monoclonal 5A2, that recognizes an epitope related to the IL-2 binding site as well as its Fab fragment, inhibits T cell growth and IL-2 internalization. Monoclonal antibody 7D4, because of its pentameric structure, probably aggregates the IL-2R at the T cell surface and therefore prevents it internalization. The data presented in this paper suggest that simple occupancy of HA-IL-2R by IL-2 is not sufficient to transduce the T cell growth signal; this signal is transmitted only after internalization of the IL-2/HA-IL-2R complex.     

Reproducible generation of autonomous malignant sublines from non-tumorogenic murine interleukin 3-dependent mast cell lines

Murine interleukin 3 (IL-3)-dependent permanent mast cell lines derived from normal mouse bone marrow were established using pokeweed mitogen-stimulated spleen cell conditioned medium (SCM) as a source of IL-3. When propagated continuously in media containing a high concentration of IL-3 (20% SCM or 20 U/ml murine recombinant IL-3 (rIL-3], all the cell lines remained strictly factor-dependent in vitro and non-tumorogenic in vivo. However, we were able to reproducibly generate autonomous sublines from cultures supplemented with low amounts of IL-3 (1% SCM or 2 U/ml rIL-3). Abrogation of exogeneous growth factor dependency was always associated with neoplastic transformation. In newly generated autonomous sublines an autocrine mechanism of growth regulation was evident in vitro.     

Interleukin 2-dependent natural killer (NK) cell lines from patients with primary T cell immunodeficiencies

Bulk cultured cell lines with natural killer (NK) activity were derived by in vitro culture with interleukin 2-containing conditioned medium (IL 2-CM) of peripheral blood mononuclear leukocytes (PBL) from patients with primary T cell deficiencies. Lines were developed from three patients with severe combined immunodeficiency (SCID) and one patient with Nezelof's syndrome and contained several populations of cells with distinct phenotypes. All lines contained a cell population expressing the Leu-5 (50K) (sheep red blood cell receptor), 3A1 (40K), and OKT10 antigens, but lacking the pan T cell antigens Leu-1 (67K) and Leu-4 (19K) as well as the markers of T cell subsets Leu-2a (32K) and Leu-3a (56K). These cells failed to express the Leu-7 antigen and only weakly expressed OKM1. In addition, one line contained a population of Leu-5+, 3A1+, OKT10+, Leu-2a+, Leu 1-, and Leu 4- cells. Three of the lines also contained populations with classic T cell (Leu-1 and-Leu 4+) phenotypes. The lines were enriched in NK activity compared with the PBL from which they were derived. Their growth was strictly dependent on IL 2-CM. Highly purified IL 2, lacking any other detectable protein contaminants or lymphokine activities, was capable of supporting the growth of the Leu-5+, 3A1+ "null" cell populations from these lines without alteration in their functional activity or phenotype. Thus, studies of in vitro expanded cell lines from patients with severe disorders of T cell function and thymic involution indicate that this "null" cell population does not require thymic maturation to develop its effector function. This "null" cell population can be maintained in vitro in the presence of IL 2. This finding is analogous to the data obtained from study of NK cells in athymic (nude) mice.     

Cell density-dependent proliferation of the murine bone marrow-derived stromal cell lines

Proliferation of three murine marrow-derived stromal cell lines, LC1, LC2, and LC3, depended on initial cell density. For LC2 and LC3, the cell density-dependence was negated by conditioned-media, indicating growth dependence on a soluble growth factor. For LC1, conditioned-media failed to stimulate proliferation, suggesting growth dependence on direct cell-cell contact.