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Query: UMLS:C0023418 (leukemia)
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Purified recombinant granulocyte colony stimulating factor (G-CSF) and interleukin-6 (IL-6) stimulated the formation of similar numbers of colonies in cultures of normal mouse marrow cells. LIF and IL-6 induced comparable differentiation in clonal cultures of murine M1 leukemic cells and exhibited enhanced actions in combination. However, LIF was 16-25-fold more active than IL-6. Induction of differentiation in M1 leukemic colonies by both LIF and IL-6 was enhanced by the addition of G-CSF or M-CSF but not by GM-CSF or Multi-CSF. Both G-CSF and IL-6, but not LIF, were able to induce differentiation in murine WEHI-3B leukemic colonies, but G-CSF was 10-fold more efficient than IL-6. Both G-CSF and IL-6 were able to stimulate the proliferation of cells of the NFS-60 continuous cell line, but G-CSF was 30-fold more efficient. M1 cells constitutively produced low levels of IL-6 and production was enhanced by LIF, but the general characteristics of the actions of LIF, IL-6, and G-CSF suggested that each operates independently as a direct differentiation inducer of leukemic cells. The similarities in the biology and actions of G-CSF, LIF, and IL-6 suggest that they may be designed to exhibit coordinated biological functions in certain situations.
Leukemia 1989 May
PMID:Actions and interactions of G-CSF, LIF, and IL-6 on normal and leukemic murine cells. 246 11

Physiological inducers of myeloid cell growth and differentiation were used to simultaneously analyze the expression of the proto-oncogenes c-myc, c-myb, c-fos, c-fes and c-fms during normal myelopoiesis, where growth is coupled to differentiation, as compared with that in leukemia, where growth has been uncoupled from differentiation as well as upon suppression of the leukemic phenotype via induction of differentiation and growth arrest. Proto-oncogene expression was also used as a tool to dissect the growth to differentiation developmental cascade. Myeloid cell growth was correlated with high c-myc and c-myb RNA levels, decreasing to undetectable levels in terminally differentiated cells. No c-myc RNA was detected in normal myeloid progenitors induced for differentiation without growth, using media conditioned by mouse granulocytes (GCM), indicating that c-myc may play either no role or an inhibitory one in differentiation. RNA levels of the proto-oncogenes c-fos, c-fes and c-fms were undetectable in normal or M1 differentiation inducible (D+) leukemic myeloblasts, and were stably induced upon stimulation of the normal precursors for growth and differentiation, with highest levels at the time when most of the cells had undergone terminal differentiation. Only c-fes RNA was induced upon M1D+ differentiation. It was also shown to be induced upon induction of differentiation without growth in normal myeloid precursors. Using c-myc and c-myb RNA suppression as molecular markers for induction of M1D+ differentiation, the existence of myeloid differentiation factor(s), distinct from myeloid growth factors, has been demonstrated. Such differentiation inducing activity was found in media conditioned by mouse lungs or granulocytes, and was induced in normal myeloid precursors by the myelopoietic growth factors IL3, GM-CSF, G-CSF, and M-CSF. Taken together, the results of this study enhance and add to previous work to better correlate the expression of the proto-oncogenes myc, myb, fes, fos and fms with several parameters of normal and abnormal myeloid cell growth and differentiation. The results indicate that the normal myeloid growth to differentiation developmental cascade entails a mechanism whereby myeloid growth factors induce myeloid differentiation factors, subsequently suppressing c-myc and c-myb RNA expression, leading to the induction of differentiation and growth arrest, including early accumulation of c-fes RNA followed by accumulation of c-fos and c-fms RNAs. It was also indicated that this cascade is impaired in leukemia.
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PMID:Proto-oncogene expression and dissection of the myeloid growth to differentiation developmental cascade. 247 Nov 31

Regulation of haemopoiesis in the marrow of patients with myelodysplastic syndromes (MDS) was evaluated by assaying (1) the production of haemopoietic regulators acting upon multipotent and committed progenitors by MDS marrow cells, and (2) the responsiveness of MDS marrow progenitors to stimulation with granulocyte colony-stimulating factor (G-CSF). The levels of multipotent progenitor cell colony-stimulating activity (CFU-GEMMCSA) in 7 d bone marrow-conditioned medium (BMCM) from MDS patients were markedly reduced as compared to controls. MDS BMCM also exhibited reduced levels of burst-promoting activity (BPA) for primitive erythroid (BFU-E) progenitors. Both CFU-GEMMCSA and BPA detected in BMCM were completely neutralized by antibodies directed against interleukin-3. MDS BMCM exhibited markedly reduced levels of murine-active CSA. This activity was partially neutralized by anti-CSF-1 antibodies. Levels of regulators in BMCM of refractory anaemia (RA), sideroblastic anaemia. RA with excess blasts, and chronic myelomonocyte leukaemia were virtually the same. CFU-GEMM and BFU-E growth in MDS marrow (n = 9) was markedly reduced. A 5-fold saturating dose of G-CSF induced an approximately 2-fold increase in CFU-GEMM in four of eight MDS and a 1.5-fold increase of BFU-E in five of nine MDS, but not in control (n = 5) marrow cell cultures. Impaired haemopoiesis in MDS marrow may be related to abnormalities both in regulator production by marrow accessory cells and in regulator responsiveness of multipotent and committed progenitors.
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PMID:Regulatory abnormalities in the marrow of patients with myelodysplastic syndromes. 247 8

We tested purified recombinant hemopoietic factors for their effects on the proliferation and differentiation of murine myelomonocytic leukemia cells (WEHI-3B-Y1) in serum-free agar culture. We found that purified recombinant human G colony-stimulating factor (CSF) markedly increased the colony number of WEHI-3B-Y1 cells and differentiation-inducing activity. However, at low colony densities [( 100/dish), G-CSF did not induce the differentiation of WEHI-3B-Y1 cells. We conclude that G-CSF does not induce the differentiation of WEHI-3B-Y1 cells directly, but induce the differentiation as a result of the secondary autoinduction of differentiation. Interleukin 3 (IL-3) slightly enhanced but erythropoietin (Epo) did not alter the colony number of WEHI-3B-Y1 cells. GM-CSF or M-CSF decreased the colony number of WEHI-3B-Y1 cells. Such purified recombinant human IL-3, Epo, GM-CSF and M-CSF did not induce morphologically the distinct differentiation of WEHI-3B-Y1 cells.
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PMID:[Clonal response of murine myelomonocytic leukemia cells (WEHI-3B-Y1) to purified recombinant human hemopoietic factors in serum-free culture]. 248 48

We have tested a panel of recombinant hematopoietic growth factors (HGF) including the interleukins (IL) 1, 2, 3, 4, and 6 and the colony stimulating factors GM-CSF, G-CSF, M-CSF for their ability to induce proliferation of precursor B acute lymphoblastic leukemia cells (ALL) from 19 patients. In Ficoll-Isopaque isolated and T cell-depleted ALL bone marrow samples, IL2 (two cases), IL3 (four cases), and GM-CSF (one case) infrequently stimulated DNA synthesis measured by 3H-thymidine (TdR) uptake, and the other recombinant growth factors completely failed to do so. In repeat experiments with ALL blasts purified by fluorescence activated cell sorting (FACS), IL2, IL3, and GM-CSF responses could not be reproduced, suggesting that nonleukemic contaminant cells, and not the ALL blasts, had been stimulated by these factors. Cocktails containing combinations of IL1-IL4 and IL6 also lacked proliferation inducing potency. Depending on the purity of the incubated ALL cell samples, an impure preparation of B cell growth factors that has been reported to contain a highly effective stimulatory activity for precursor B ALL cells induced proliferation of residual normal cells as well as the ALL cells, as was evident from combined analysis of DNA synthesis and karyotyping. Exposure of the ALL blasts to artificial activators of protein kinase C and Ca2+ mobilization resulted in significant rises in 3H-TdR uptake, suggesting that these intracellular compounds are involved in transducing signals that upregulate proliferation. Although it remains possible that some of the human recombinant growth factors promote the growth of precursor B ALL cells in combination with other stimuli, a dominant role in the regulation of proliferation of these cells cannot be attributed to any of these cytokines at the present time.
Leukemia 1989 May
PMID:Recombinant hematopoietic growth factors fail to induce a proliferative response in precursor B acute lymphoblastic leukemia. 249 81

The c-fms protooncogene encodes the receptor for the colony-stimulating factor 1 of macrophages. Its transforming counterpart, the v-fms oncogene has previously been recognized as the transforming gene of the McDonough strain of feline sarcoma virus. We have isolated rabbit antisera against a 115-kDa recombinant polypeptide containing the 926 carboxy-terminal amino acids of the v-fms protein. All antibodies recognized the cytoplasmic domain of the v-fms protein, which is 95% homologous to the corresponding domain of human c-fms proteins. These sera were applied in a survey of various human cancer cell lines, such as peripheral blood mononuclear (HL60) and choriocarcinoma (BeWo) cells, as well as leukemic cells from 58 patients with acute myelocytic, chronic myelocytic or acute lymphocytic leukemias (AML, CML, ALL). Significantly enhanced levels of fms-specific tyrosine kinase activity were detected in 12-O-tetradecanoylphorbol-13-acetate-induced HL60 and in BeWo cells, and in 7 out of 24 samples from AML patients, whereas no activity could be detected in 9 ALL or in 25 CML cell preparations. The AML cells were classified according to the FAB criteria. The highest incidence of increased fms activity was found in cells assigned to the M4 class (four out of five cases). While no activity was found in material belonging to FAB classes M2 or M3, one of the two cases of the M5 class was kinase-positive. Interestingly, two out of seven cases of the M1 class cells exhibited enhanced levels of fms kinase. These data suggest that the determination of the fms kinase may be useful to subdivide the M1 class of the FAB classification into monocytic and non-monocytic precursor leukemia cells.
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PMID:Detection of fms-oncogene-specific tyrosine kinase activity in human leukemia cells. 252 17

In order to delineate the humoral regulation of eosinophil production, we studied the effects of interleukin-3 (IL-3), granulocyte/macrophage colony-stimulating factor (GM-CSF), and interleukin-5 (IL-5), and their combinations on eosinophil colony formation in clonal cell culture. We plated 1,000 bone marrow null cells per dish and in some experiments used polyclonal anti-gibbon IL-3 sera and anti-human GM-CSF. IL-3 or GM-CSF independently from each other supported eosinophil colony formation. Although IL-5 supported formation of small eosinophil colonies, the number of colonies were significantly smaller than that supported by GM-CSF or IL-3. Cytological examination of the constituent cells revealed that some of the apparent eosinophil colonies supported by IL-3 and GM-CSF were mixed colonies containing eosinophils and one or more other lineages. In addition, the majority of the eosinophils seen in cultures with IL-3 and/or GM-CSF proved to be early eosinophil precursors including eosinophilic promyelocytes, myelocytes, and meta-myelocytes. IL-5-supported eosinophil colonies were pure eosinophil colonies and contained mostly maturer eosinophils such as band and segmented forms. These observations indicated that the developmental stages of the targets of IL-3 and GM-CSF are earlier than those of IL-5 and that the primary function of IL-5 is to support terminal maturation of eosinophils.
Leukemia 1989 Jan
PMID:Humoral regulation of eosinophilopoiesis in vitro: analysis of the targets of interleukin-3, granulocyte/macrophage colony-stimulating factor (GM-CSF), and interleukin-5. 264 72

Considerable progress has been made over the last 5 years in defining the exact factors which make up 'colony-stimulating activity', the cells that produce individual CSFs, and determining some of the stimuli that lead to secretion of specific CSFs. There is much to learn however about the mechanisms of CSF action, and also much to learn about the role these factors play in hematopoietic regulation in vivo. The role, if any, of marrow stromal cells in the production of CSFs is particularly important and needs much clearer definition. Much of our understanding of CSF activity has been previously dependent on in vitro bioassays which were sensitive but frequently imprecise. The availability of purified recombinant protein has alleviated the reliance on conditioned media. Previously used conditioned media frequently contained multiple growth factors and inhibitory factors. The cloning of the CSFs has revealed both structural homology and diversity. The conserved genomic structural schema between the majority of the CSFs suggest a common ancestral gene. However, M-CSF diverges from this schema. Conserved also is the 3' untranslated motif of AUUUA in the majority of CSFs. M-CSF is again divergent in this respect. However, where regulation of the mRNA transcript level has been characterized carefully, normal cells appear to regulate CSF mRNAs primarily in a post transcriptional manner. The regulation of CSF transcription in leukemia is complex. In retrovirally mediated leukemia, CSF production is due to increased transcription mediated by the retrovirus. In the few cases of human leukemias making CSFs which have been studied, evidence for both post-transcriptional regulation and structural rearrangements in the CSF genes has been presented. Due to the extreme rarity of normal hematopoietic progenitor cells that correspond to the same state of differentiation as that of the leukemic blast forms, several questions remain. Do normal progenitor cells also make CSFs at some stages of differentiation? What role, if any, do CSFs play in leukemogenesis? The rapid development of our understanding of CSFs over the past several years has led to a much better understanding of hematopoiesis. As we understand more of normal hematopoiesis we also begin to understand the complexities involved in the abnormal regulation as in myelogenous leukemias. With the powerful tools currently available we can be much more precise in our understanding of the intricacies involved.
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PMID:Regulation of colony-stimulating factor production by normal and leukemic human cells. 266 34

Normal human bone marrow was grown as xenografts in mice immune-suppressed by thymectomy and total body irradiation. Mononuclear cell fractions isolated from marrow harvests from 17 donors all gave rise to subcutaneous nodules which grew to a variable maximum size and then regressed. Human granulocyte/macrophage progenitors (CFU-GM) were recovered from xenografts up to 20 days postimplantation. Xenograft growth, measured by maximum nodule volume, area under the growth curve, and rate of regression, did not correlate with the speed of neutrophil or platelet recovery in bone marrow transplant patients infused with the same marrow. Assay of numbers of stromal fibroblastoid colony forming cells (CFU-F) in donor marrow was also not predictive of subsequent hemopoietic recovery in recipients. Treatment of host animals with daily intraperitoneal injections of 100 micrograms/kg human recombinant granulocyte/macrophage colony stimulating factor produced a more rapid growth of subcutaneous nodules. This technique may therefore be of use in determining the in vivo efficacy of human hemopoietic regulatory factors.
Leukemia 1989 Sep
PMID:Growth of xenografted human bone marrow: comparison with hemopoietic reconstitution in patients after allogeneic bone marrow transplant and response to granulocyte macrophage colony stimulating factor. 266 55

The conversion of normal haemopoietic stem cells to myelodysplastic and then to leukaemic cells is marked by a number of events leading to progressive genetic changes in the abnormal clonal population. Cytogenetic evidence points to abnormalities at specific chromosomal locations, commonly involving chromosomes 5 and 7, where there are a particular concentration of genes directly involved in the regulation of haemopoietic proliferation and differentiation. These include GM-CSF, IL-3, M-CSF, erythropoietin and others. Other genes that may be involved in the preleukaemic process are so-called 'oncogenes' such as met on chromosome 7q and fms on 5q (which codes for the M-CSF receptor) that may be deleted or translocated. The ras gene family is activated by point mutations in a wide variety of malignant states, including myelodysplasia and acute myeloblastic leukaemia. At the present time we do not know the cause of these genetic lesions, their functional significance or the sequence in which they occur.
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PMID:Oncogenes in the myelodysplastic syndrome. 267 42

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