Monoclonal antibodies to mammalian D-type G1 cyclins.

D-type cyclins are necessary and rate-limiting for G1 progression during the mammalian cell cycle. Cyclins D1, D2, and D3 are encoded by distinct genes and are expressed in proliferating cells in a lineage-specific manner. Monoclonal antibodies (mAbs) generated to bacterially produced recombinant D-type cyclins were able to react with the native proteins expressed in mammalian cells. One mouse and three rat mAbs immunoprecipitated cyclin D1 from mouse macrophages. Only rat mAbs reacted with human cyclin D1 and cross-reacted with cyclin D2 expressed in proliferating T lymphocytes and human tumor cell lines. A single rat mAb to cyclin D2 exhibited a pattern of reactivity reciprocal to that of rat mAbs to D1. Three rat mAbs reacted specifically with mouse or human cyclin D3, but did not cross-react with cyclins D1 or D2 from either species. Representative mAbs were useful for immunoblotting and detected D-type cyclins coprecipitating in complexes recovered with antiserum to cyclin-dependent kinase-4 (CDK4). Because these mAbs detect D-type cyclins in the nuclei of fixed permeabilized cells, they should prove useful in documenting cyclin overexpression in those human tumors in which the genes are amplified or are targets of specific chromosomal rearrangements.

Interferon-gamma stimulates the survival and influences the development of bipotential granulocyte-macrophage colony-forming cells.

The effects of interferon-gamma (IFN-gamma) on a highly enriched population of granulocyte-macrophage colony-forming cells (GM-CFC) were assessed. When added with myeloid growth factors (interleukin-3 [IL-3], granulocyte-macrophage colony-stimulating factor [GM-CSF], or macrophage-CSF [M-CSF]), IFN-gamma inhibited the formation of colonies in soft agar assays. Furthermore IFN-gamma stimulated an increase in the number of macrophages present in colonies formed in the presence of IL-3. IFN-gamma also inhibited M-CSF-, GM-CSF-, or IL-3-stimulated [3H]-thymidine incorporation in highly enriched GM-CFC. However, when added in the absence of hematopoietic growth factors, IFN-gamma promoted the survival of GM-CFC and had a modest stimulatory effect on DNA synthesis. The direct interaction of the IFN with GM-CFC was confirmed by showing its ability to rapidly activate the sodium/hydrogen antiport in GM-CFC, as do the mitogens GM-CSF, M-CSF, and IL-3. However, the effect of IFN-gamma on intracellular pH and DNA synthesis was transient and pretreatment with IFN markedly inhibited the ability of GM-CSF, M-CSF, and IL-3 to activate the sodium/hydrogen antiport. IFN-gamma has a dual effect on GM-CFC, decreasing the rate of cell death but also limiting the proliferative response to CSFs.

Control of proliferation by myeloid growth factors.

At present the molecular events which regulate the proliferation and developmental fates of haemopoietic cells are poorly understood. Until recently, the only receptor for the myeloid growth factors which had been characterized extensively was that for M-CSF (c-fms). The molecular cloning of receptors for IL-3, GM-CSF and G-CSF should now permit rapid progress in the analysis of receptor-mediated haemopoietic cell differentiation and development, and should also reveal how the process of leukaemic transformation effects these events.

Development of multipotential haemopoietic stem cells to neutrophils is associated with increased expression of receptors for granulocyte macrophage colony-stimulating factor: altered biological responses to GM-CSF during development.

Interleukin-3 (IL-3) dependent multipotent haemopoietic stem cells FDCP-Mix A4 (A4) were induced to differentiate and develop into mature neutrophils in response to Granulocyte Macrophage Colony Stimulating Factor (GM-CSF) plus granulocyte CSF (G-CSF). This resulted in an increase in cell number over seven days of culture, following which the cells lost the ability to undergo further proliferation. The effect of GM-CSF on these cells has been assessed at various stages of development. Clonogenic cells, able to respond to GM-CSF, were generated only at days 3, 4 post-induction. From day 5 onwards, mature post-mitotic neutrophils are produced and clonogenic cells are lost. Loss of proliferative potential, in response to GM-CSF, was confirmed using [3H]-thymidine incorporation. Receptors for GM-CSF, were also measured during development using [125I]-GM-CSF binding assays. Although the dissociation constant for GM-CSF binding sites did not vary considerably, the number of such sites increased dramatically from about 20 (day 0, when the cells have a primitive morphology) to about 1000 by day 6 (when the cells are predominantly mature neutrophils). GM-CSF-stimulated Na+/H+ antiport activation was also determined. Although few GM-CSF receptors are expressed at day 0, there is a significant response (63% of maximal) to GM-CSF in terms of intracellular alkalinisation: this response increased markedly until, by day 4 (700 GM-CSF binding sites/cell), there is a maximal activation of the antiport by GM-CSF. By day 7 (greater than 900 GM-CSF binding sites/cell), however, there is significant reduction in activation of the Na+/H+ antiport by GM-CSF. Nonetheless, increased viability of these mature cells is still seen in response to GM-CSF. These results suggest that not only does expression of GM-CSF receptors alter during development of multipotential cells to mature neutrophils, but that these receptors are coupled to different intracellular effector mechanisms as the cells progressively mature.

Chemotactic peptides but not macrophage colony stimulating factor effect the synthesis of inositol lipids in macrophages.

Normal bone marrow derived macrophages display a wide variety of biological responses to a number of distinct agonists, for example, Macrophage Colony Stimulating Factor (M-CSF) and chemotactic peptides (such as FMLP). FMLP stimulates reactive oxygen intermediate production in these cells, whilst M-CSF stimulates DNA synthesis. We have compared the effects of these two agents on the production of novel inositol lipids in macrophages. Evidence is presented that FMLP, but not M-CSF elevate the levels of a lipid putatively identified as phosphatidylinositol-3,4-bisphosphate. The implications of this observation on proposed role of novel inositol lipids in macrophage proliferation are discussed.

Granulocyte-macrophage colony-stimulating factor can stimulate macrophage proliferation via persistent activation of Na+/H+ antiport. Evidence for two distinct roles for Na+/H+ antiport activation.

Macrophages respond to a variety of extracellular stimuli which can modulate the proliferation, development, activation and functional activity of these cells. The effects of two such agents, granulocytemacrophage colony-stimulating factor (GM-CSF, which stimulates proliferation) and platelet-activating factor (PAF, which stimulates chemotaxis and bactericidal activity), on cellular signal transduction mechanisms were compared. PAF can stimulate inositol lipid hydrolysis leading to Ca2+ mobilization. GM-CSF on the other hand has no effect on these events. Both agonists do, however, share an ability to activate an amiloride-sensitive Na+/H+ antiport and, furthermore, amiloride analogues are shown to inhibit the proliferative effects of GM-CSF on these cells. Long-term incubations with either PAF or GM-CSF demonstrate that it is only those cells pretreated with the latter which show a persistent activation of the antiport together with a sustained increase in intracellular pH. PAF-treated cells exhibit only a transitory increase in antiport activity, their intracellular pH levels returning to resting levels in spite of the continuous presence of the agonist in the medium. These effects of GM-CSF and PAF on Na+/H+ exchange are observed in both bicarbonate-free and bicarbonate-containing medium. These results lead us to suggest that the Na+/H+ antiport has a role in macrophage proliferation and in the regulation of intracellular pH during the oxidative burst stimulated by PAF and other agonists, and that differential mechanisms whereby this antiport is regulated exist in macrophages.

The biochemistry and biology of the myeloid haemopoietic cell growth factors.

In the adult, blood cell production or haemopoiesis takes place mainly in the bone marrow. The blood cell types produced are a reflection of the needs of the organism at any moment, for example bacterial infection leads to a large increase in neutrophil production. The rate and scale of blood cell production in vivo are regulated, at least in part, by the synthesis and release of specific cytokines both within the bone marrow and also from other tissues. Here we detail the range of cytokines which act directly on haemopoietic stem cells and myeloid progenitor cells. Also cellular systems which will permit the elucidation of the specific interactions between these various cytokines which regulate stem cell self-renewal, differentiation and proliferation are described.

Interleukin-3-stimulated haemopoietic stem cell proliferation. Evidence for activation of protein kinase C and Na+/H+ exchange without inositol lipid hydrolysis.

Interleukin 3 (IL-3) is an important regulator of haemopoietic stem cell proliferation both in vivo and in vitro. Little is known about the possible mechanisms whereby this growth factor acts on stem cells to stimulate cell survival and proliferation. Here we have investigated the role of intracellular pH and the Na+/H+ antiport in stem cell proliferation using the multipotential IL-3-dependent stem cell line, FDCP-Mix 1. Evidence is presented that IL-3 can stimulate the activation of an amiloride-sensitive Na+/H+ exchange via protein kinase C activation. IL-3-mediated activation of the Na+/H+ exchange is not observed in FDCP-Mix 1 cells where protein kinase C levels have been down-modulated by treatment with phorbol esters. Also the protein kinase C inhibitor H7 can inhibit IL-3-mediated increases in intracellular pH. This activation of Na+/H+ exchange via protein kinase C has been shown to occur with no measurable effects of IL-3 on inositol lipid hydrolysis or on cytosolic Ca2+ levels. Evidence is also presented that this IL-3-stimulated alkalinization acts as a signal for cellular proliferation in stem cells.