Cytokine-dependent granulocytic differentiation. Regulation of proliferative and differentiative responses in a murine progenitor cell line

Human granulocyte colony stimulating factor (G-CSF) can support the survival and short term proliferation of the interleukin 3 (IL 3)-dependent diploid murine hemopoietic progenitor cell line 32D C13. After 8 days in the presence of 30 U/ml of G-CSF and in the absence of IL 3, the great majority of 32D C13 cells becomes positive for myeloperoxidase (a marker that appears at the promyelocytic stage of the granulocytic lineage) and progressively differentiates into lactoferrin-containing neutrophilic granulocytes. Myeloperoxidase mRNA rapidly increases after 24 to 48 hr of treatment with G-CSF, peaks at day 6 and is no longer detectable at day 9 and 12, paralleling the appearance of myeloperoxidase-positive promyelocytes and myelocytes in the culture. After 12 days, 100% of the cells terminally differentiate, and clonogenic assays in IL 3-containing semisolid media indicate that the whole population has irreversibly lost proliferative capability. By using varying concentrations of both murine IL 3 and recombinant human G-CSF, the cultures develop an heterogeneous population of cells representing all the differentiation stages of the myeloid lineage, and the relative ratios of immature proliferating precursors and terminally differentiated cells present in the cultures can be modulated by modifying the concentrations of IL 3 or recombinant human G-CSF. Isobolic curves indicate that IL 3 and G-CSF have an antagonistic effect on the proliferation of 32D C13 cells. Thus, these cells represent a simplified in vitro model of normal granulocytic differentiation whose extent may be modulated completely in the presence of serum by two well-defined growth and differentiation factors: IL 3 and G-CSF.     

Regulation of granulocyte and macrophage populations of murine bone marrow cells by G-CSF and CD137 protein

Background

Granulocytes and monocytes/macrophages differentiate from common myeloid progenitor cells. Granulocyte colony-stimulating factor (G-CSF) and CD137 (4-1BB, TNFRSF9) are growth and differentiation factors that induce granulocyte and macrophage survival and differentiation, respectively. This study describes the influence of G-CSF and recombinant CD137-Fc protein on myelopoiesis.

Methodology/Principal Findings

Both, G-CSF and CD137 protein support proliferation and survival of murine bone marrow cells. G-CSF enhances granulocyte numbers while CD137 protein enhances macrophage numbers. Both growth factors together give rise to more cells than each factor alone. Titration of G-CSF and CD137 protein dose-dependently changes the granulocyte/macrophage ratio in bone marrow cells. Both factors individually induce proliferation of hematopoietic progenitor cells (lin^-, c-kit⁺) and differentiation to granulocytes and macrophages, respectively. The combination of G-CSF and CD137 protein further increases proliferation, and results in a higher number of macrophages than CD137 protein alone, and a lower number of granulocytes than G-CSF alone demonstrating that CD137 protein-induced monocytic differentiation is dominant over G-CSF-induced granulocytic differentiation. CD137 protein induces monocytic differentiation even in early hematopoietic progenitor cells, the common myeloid progenitors and the granulocyte macrophage progenitors.

Conclusions/Significance

This study confirms earlier data on the regulation of myelopoiesis by CD137 receptor - ligand interaction, and extends them by demonstrating the restriction of this growth promoting influence to the monocytic lineage.     

Interleukin-3

Interleukin-3 (IL-3) is a hemopoietic growth factor involved in the survival, proliferation and differentiation of multipotent hemopoietic cells. In five mammalian species, including man, the gene encoding IL-3 has been isolated and expressed to yield the mature recombinant proteins. The human IL-3 gene encodes a protein of 133 amino acids with two conserved cysteine residues and 2 potential N-linked glycosylation sites; human native IL-3 has not been characterized. Comparison of the IL-3 genes revealed a more rapid evolutionary divergence than has been observed for other hemopoietic growth factors, and, hence, a more pronounced species specificity of the functional proteins was found. In agreement with its stimulatory action on immature multipotent cells, thein vivo actions of homologous recombinant IL-3 in nonhuman primates include a highly increased production of blood cells along the neutrophilic, eosinophilic and basophilic granulocyte as well as the monocyte, red cell and platelet lineages.     

24p3 in differentiation of myeloid cells

24p3 is a secreted lipocalin that has been variously related to apoptosis, proliferation, and the neutrophil lineage of blood cells. We have investigated the expression of 24p3 mRNA and protein in myeloid cell lines induced to differentiate by insulin-like growth factor 1 (IGF-1) and the granulocytic-colony simulating factor (G-CSF). Both these growth factors, which cause myeloid cells to differentiate into granulocytes, induced a marked increase in the expression of both 24p3 protein and mRNA. The mRNA especially appeared early after the cells were induced with either IGF-1 or G-CSF, at a time when the cells were still proliferating and are morphologically undifferentiated. 24p3 can be considered an early marker of granulocytic differentiation.     

1,25-Dihydroxycholecalciferol-induced differentiation of myelomonocytic leukemic cells unresponsive to colony stimulating factors and phorbol esters

The murine myelomonocytic leukemia cell line WEHI-3B D+, which differentiates in response to granulocyte colony stimulating factor (G-CSF), can also be induced to differentiate into monocyte-macrophages by phorbol myristate acetate (PMA) treatment, whereas the WEHI-3B D- subline, which is unresponsive to G-CSF and PMA, can be induced to differentiate to granulocytes as well as monocytes by 1,25-dihydroxycholecalciferol [1,25-(OH)2 D3], the biologically active metabolite of vitamin D3. A newly developed variant of the WEHI-3B D+ line, named WEHI-3B D+ G, which was responsive to G-CSF but not to PMA, was also differentiated to granulocytes by 1,25-(OH)2 D3. Although vitamin D3 has been reported to induce macrophage differentiation in responsive tumor cells, this is the first demonstration that 1,25-(OH)2 D3 can induce granulocyte differentiation. In both differentiation pathways, cessation of cellular proliferation accompanies changes in morphologic and cytochemical properties of the cells. This suggests that leukemic cell lines unresponsive to differentiation agents acting at the cell surface retain their ability to differentiate in response to agents that do not act via the plasma membrane such as 1,25-(OH)2 D3, which has cytosolic/nuclear receptors. Vitamin D3 could act through different cellular pathways inducing differentiation or by bypassing only the first step of a common differentiation cascade used by agents with cell surface receptors such as CSF. These results suggest that low doses of 1,25-(OH)2 D3 may be useful in combination with hemopoietic growth factors (CSFs) as therapeutic agent to induce leukemic cell differentiation in vivo.     

Expression profiles of micro RNA in proliferating and differentiating 32D murine myeloid cells

32D cells are murine myeloid cells that grow indefinitely in Interleukin-3 (IL-3). In these cells, the type 1 insulin-like growth factor (IGF-I) and granulocytic-colony stimulating factor (G-CSF) induce differentiation to granulocytes. 32D cells do not express insulin receptor substrate-1 (IRS-1) or IRS-2, docking proteins of the IGF-I receptor. Ectopic expression of IRS-1 in these cells inhibits differentiation, the cells become IL-3 independent and IGF-1 dependent and can form tumors in mice. 32D and 32D-derived cells offer a good model in which to study the expression profiles of Micro Rna (miR) related to sustained proliferation or differentiation. We present here the data obtained with miR micro-arrays and identify the miR that are regulated by IGF-1 or G-CSF and are associated with either differentiation or indefinite cell proliferation of 32D murine myeloid cells.     

Localization of the human G-CSF gene to the region of a breakpoint in the translocation typical of acute promyelocytic leukemia

Summary The colony-stimulating factors regulate growth, differentiation, and function of blood cells. The effect of granulocyte colony-stimulating factor (G-CSF) on myeloid leukemias is unique among colony-stimulating factors in driving the leukemic cells from a self-renewing malignant state to a mature differentiated phenotype with the concomitant loss of tumorigenicity. This property of G-CSF has led to suggestions that its absence is responsible for lack of differentiation of leukemic cells and that the therapeutic administration of G-CSF could reverse this defect and result in a cure for leukemia. Here we show that the gene coding for human G-CSF is localized to chromosome 17, bands q11.2-21. The translocation of the long arm of chromosome 17 at q12-21 to chromosome 15 is a specific abnormality occurring in a high proportion of, if not all, patients with acute promyelocytic leukemia, a disease characterized by undifferentiated myeloid cells and a dismal prognosis. Abnormalities of the regulation of a specific differentiation factor gene mediated by a specific chromosomal rearrangement may be directly implicated in the pathogenesis of human leukemia.     

Induction of the granulocyte-macrophage colony-stimulating factor (CSF) receptor by granulocyte CSF increases the differentiative options of a murine hematopoietic progenitor cell.

32DC13(G) is an interleukin-3-dependent murine hematopoietic precursor cell line which differentiates into neutrophilic granulocytes upon exposure to granulocyte colony-stimulating factor (G-CSF) but ceases to proliferate and dies when exposed to granulocyte-macrophage (GM)-CSF. Surface receptors for GM-CSF are undetectable on 32DC13(G) cells but can be induced by priming the cells with G-CSF. Exposure of the G-CSF-primed cells to GM-CSF then results in the generation of monocytes as well as granulocytes. The acquired competence to respond to GM-CSF remains irreversibly encoded in the primed cells, although the GM-CSF receptor can be down regulated by interleukin-3. This phenomenon suggests a mechanism by which hematopoietic precursors may obtain additional receptors, thereby increasing their differentiative potential.     

Receptor binding and mitogenic effects of insulin and insulinlike growth factors I and II for human myeloid leukemic cells

Insulin and insulinlike growth factors I and II (IGF-I and IGF-II) influence mesodermal cell proliferation and differentiation. As multiple growth factors are involved in hemopoietic cell proliferation and differentiation, we assessed the receptor binding and mitogenic effects of these peptides on a panel of mesodermally derived human myeloid leukemic cell lines. The promyelocytic cell line HL60 had the highest level of specific binding for these 125I-labeled ligands, with lower binding to the less differentiated myeloblast cell line KG1 and undifferentiated blast variants of these cell lines (HL60blast, KG1a). Insulin binding affinity and receptor numbers were reduced significantly by chemically induced granulocytic differentiation of HL60 cells and was unchanged following induced monocytic differentiation. No substantial alteration in IGF-I or -II binding occurred with induced HL60 cell differentiation. Insulin and IGF-I demonstrated cross competition for receptor binding and down-regulated their homologous receptors without detectable cross modulation of the heterologous receptors on HL60 cells. IGF-I and insulin increased HL60 cell proliferation, as assessed by 3H-thymidine uptake, IGF-I greater than insulin. IGF-I binding and mitogenic effects were blocked by the monoclonal anti-IGF-I receptor antibody IR3, indicating that IGF-I-induced proliferative effects were mediated via its homologous receptor. In contrast, insulin binding and mitogenesis displayed blocking by both anti-IGI-I and anti-insulin receptor antibodies, indicating mediation of its activity through both receptors. These data demonstrate specific binding and mitogenic interactions between insulin, IGFs, and hemopoietic cells which are associated with their state of differentiation.     

Expression of CD7 on normal human myeloid progenitors.

Existence of biphenotypic leukemias co-expressing CD7 and CD34 has prompted the question of whether a similar population of cells is present in normal human bone marrow. As CD7 is considered to be a T cell-restricted Ag, the co-expression of CD7 with the "human stem cell Ag" CD34 may identify a bipotent stage within hemopoietic differentiation. Cells with this phenotype have previously been isolated from human thymus. In this report we provide evidence that human marrow mononuclear cells also contain a minor subpopulation of cells co-expressing CD7 and CD34. The CD7+/CD34+ cells were found to contain committed myeloid progenitors assayed both as CFU in semi-solid media and by their ability to produce granulocytes in long term marrow cultures. Expression of CD7 on myeloid committed progenitors was further confirmed in a C-mediated cytotoxic assay. We conclude that CD7 expression is not restricted to T cells but is also expressed during early stages of myeloid differentiation.     

Down-modulation of receptors for granulocyte colony-stimulating factor on human neutrophils by granulocyte-activating agents

Purified human blood neutrophils were able to bind radioiodinated murine granulocyte-colony-stimulating factor (G-CSF) in a specific manner. This factor has previously been shown to stimulate functional activities of human and murine neutrophilic granulocytes and to be functionally analogous to human-derived CSF beta. The binding of 125I G-CSF to human neutrophils was competed for equally by unlabeled G-CSF and CSF beta but not by other CSF's. Saturation analysis indicated that human neutrophils displayed about 700-1,500 receptors for G-CSF/CSF beta per cell. Three other agents (N-formyl-methionine-leucine phenylalanine, bacterial lipopolysaccharide, and human CSF alpha) known to activate neutrophils did not compete directly for G-CSF binding sites but, in preincubation experiments at 37 degrees C, were able to down-modulate the expression of G-CSF receptors on human neutrophils in a dose- and time-dependent manner. This effect was specific since the same agents have been shown elsewhere to up-regulate the expression of other granulocyte surface antigens and other agents were much less effective at down-modulating G-CSF receptors. Since the granulocyte-activating agents increase the sensitivity of human neutrophils to G-CSF/CSF beta and mimic some of the actions of G-CSF on neutrophils, it is suggested that G-CSF receptor down-modulation might be a mechanism whereby these agents activate G-CSF receptors and thereby exert some of their effects.     

Differential roles of vascular endothelial growth factor receptors 1 and 2 in dendritic cell differentiation

Impaired Ag-presenting function in dendritic cells (DCs) due to abnormal differentiation is an important mechanism of tumor escape from immune control. A major role for vascular endothelial growth factor (VEGF) and its receptors, VEGFR1/Flt-1 and VEGFR2/KDR/Flk-1, has been documented in hemopoietic development. To study the roles of each of these receptors in DC differentiation, we used an in vitro system of myeloid DC differentiation from murine embryonic stem cells. Exposure of wild-type, VEGFR1(-/-), or VEGFR2(-/-) embryonic stem cells to exogenous VEGF or the VEGFR1-specific ligand, placental growth factor, revealed distinct roles of VEGF receptors. VEGFR1 is the primary mediator of the VEGF inhibition of DC maturation, whereas VEGFR2 tyrosine kinase signaling is essential for early hemopoietic differentiation, but only marginally affects final DC maturation. SU5416, a VEGF receptor tyrosine kinase inhibitor, only partially rescued the mature DC phenotype in the presence of VEGF, suggesting the involvement of both tyrosine kinase-dependent and independent inhibitory mechanisms. VEGFR1 signaling was sufficient for blocking NF-kappaB activation in bone marrow hemopoietic progenitor cells. VEGF and placental growth factor affect the early stages of myeloid/DC differentiation. The data suggest that therapeutic strategies attempting to reverse the immunosuppressive effects of VEGF in cancer patients might be more effective if they specifically targeted VEGFR1.     

Biological activity of human granulocyte colony stimulating factor with a modified C-terminus

Granulocyte colony-stimulating factor (G-CSF) undergoes receptor-mediated internalization into target cells which are normally restricted to neutrophilic granulocytes and their committed progenitor cells, suggesting that it may be applicable as a myeloid cell-targeting vehicle. To test this notion, we constructed a cDNA encoding a human G-CSF/murine stem cell factor (mSCF) chimeric molecule in a mammalian expression vector and transfected NIH3T3 cells with this plasmid. The resulting chimeric cytokine consisted of the entire G-CSF sequences fused to Lys148 of mSCF. It can be released from the surface membrane of NIH3T3 transformants through proteolytic cleavage at Ala164 of mSCF. The culture media conditioned by a number of stable transformants, which were confirmed by an enzyme-linked immunosorbent assay (ELISA) to secrete an hG-CSF derivative, were examined for their ability to stimulate CFU-G-derived colony formation as well as the proliferation of G-CSF-dependent NFS-60 cells. The results indicated that this C-terminus modified version of hG-CSF is as potent as recombinant hG-CSF in both assays.     

Expression of the Evi-1 zinc finger gene in 32Dc13 myeloid cells blocks granulocytic differentiation in response to granulocyte colony-stimulating factor.

Expression of the Evi-1 gene is frequently activated in murine myeloid leukemias by retroviral insertions immediately 5' or 90 kb 5' of the gene. The Evi-1 gene product is a nuclear, DNA-binding zinc finger protein of 145 kDa. On the basis of the properties of the myeloid cell lines in which the Evi-1 gene is activated, it has been hypothesized that its expression blocks normal differentiation. To explore this proposed role, we have constructed a retrovirus vector containing the gene and examined its effects on an interleukin-3-dependent myeloid cell line that differentiates in response to granulocyte colony-stimulating factor (G-CSF). Expression of the Evi-1 gene in these cells did not alter the normal growth factor requirements of the cells. However, expression of the Evi-1 gene blocked the ability of the cells to express myeloperoxidase and to terminally differentiate to granulocytes in response to G-CSF. This effect was not due to altered expression of the G-CSF receptor or to changes in the initial responses of the cells to G-CSF. These results support the hypothesis that the inappropriate expression of the Evi-1 gene in myeloid cells interferes with the ability of the cells to terminally differentiate.     

Granulocyte colony-stimulating factor receptor: Stimulating granulopoiesis and much more

The granulocyte colony-stimulating factor receptor (G-CSFR) plays an important role in the production, survival and activation of neutrophilic granulocytes during both normal and emergency hematopoiesis. The G-CSFR also participates in the development of other myeloid lineages, the mobilization of hematopoietic stem cells and myeloid cell migration. This has lead to several important clinical applications for its ligand, G-CSF. More recently, additional important roles for G-CSFR have emerged outside the hematopoietic system, such as in the protection and repair of a diverse range of tissues, including muscle, liver and neural tissue, providing further scope for developing G-CSF as a therapeutic agent. The G-CSFR has also been implicated in the etiology of disease, with mutations/variants of G-CSFR implicated in neutropenia, myelodysplasia and leukemia. Additionally, autocrine/paracrine stimulation of G-CSFR may be important in the biology of solid tumors, including metastasis.     

Terminal differentiation of hemopoietic cell clones cultured in tridimensional collagen matrix: in situ cell morphology and enzyme histochemistry analysis

Collagen, a major component of the extracellular matrix in vivo, has been used as a tridimensional gel matrix for cultured hemopoietic clones. Its resemblance to the natural matrix produced by cells makes it ideal for studies on proliferation and differentiation of hemopoietic lineages. Every lineage, including granulocytes (basophilic, eosinophilic and neutrophilic polymorphs) monocyte-macrophages, megakaryocytes, erythroid and lymphoid lineages could be grown using a standardized collagen medium, provided that specific stimulators were added in the culture. Clones were scored on either live or fixed cultures. Compared to other gel substrates, collagen matrix proved superior for cell proliferation and maturation. Additional advantages (in situ clonal analysis by histological staining, enzyme cytochemistry), and other possibilities of the method are reported and discussed. The system offers great potential for cellular immunology, hematology and molecular biology with peculiar reference to differentiation of normal hemopoietic cells, viral transformation and leukemogenesis in vitro. These applications are reviewed.