UMLS:C0596978 - FACTA Search

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Query: UMLS:C0596978 (Leukemia)
15,069 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We analyzed the maintenance of acute myeloid leukemia clonogenic cells (AML CFU-L) in liquid culture in the presence of five potential differentiation inducers: trans-retinoic acid, 1,25-dihydroxy vitamin D3, interferon gamma, granulocyte colony-stimulating factor (G-CSF), macrophage colony-stimulating factor (M-CSF), used singly and with two combined. The culture medium contained either fetal bovine or human serum from normal donors. CFU-L recovery after 7 days was compared to that observed in control cultures. Of AML cases and HL60 cells, 11/15 displayed greater than 50% CFU-L reduction in response to one or more inducers. In 8/9 responsive cases that underwent the nitroblue tetrazolium (NBT) reduction test, an increase in the percentage of functionally mature (NBT-positive) cells was detected. The combination of retinoic acid with interferon gamma was most effective in reducing CFU-L recovering (8 responsive/15 AML cases), G-CSF and M-CSF displayed either inhibitory or stimulatory activity in different AML cases. The type of serum employed generally did not affect the response to inducers of differentiation. No significant inhibition of the recovery of granulocyte-macrophage colony-forming units was determined by the five inducers in experiments with three normal bone marrow samples. Our experiments indicate that biological differentiation inducers can reduce AML CFU-L self-renewal and increase the proportion of differentiated cells at concentrations that do not affect normal myelopoiesis and could be achieved during treatments in vivo.
Leukemia 1992 Feb
PMID:Self-renewal inhibition of acute myeloid leukemia clonogenic cells by biological inducers of differentiation. 137 69

Tumor necrosis factor (TNF) is a macrophage-derived cytokine that causes hemorrhagic necrosis of several human tumors in vitro. It has a wide range of biologic effects including stimulation of secretion of both granulocyte colony-stimulating factor (G-CSF) and granulocyte/macrophage colony-stimulating factor (GM-CSF) by normal adult lung fibroblasts in culture. No in vivo data are available on the effect of exogenously administered TNF on cytokine production. In the studies reported here, we show that G-CSF accumulates in the serum in vivo in response to recombinant TNF (rTNF) administration. At the peak of the response circulating levels of 2-6 ng/ml of biologically active G-CSF are detectable. Surprisingly, circulating levels of GM-CSF, interleukin-3 as well as a number of other cytokines were not detectable within the limits of the assays. The results indicate that the levels of GM-CSF or interleukin-3 are minimally 100-fold lower than the peak levels of G-CSF. These data illustrate the complex interplay that cytokines have in vivo. Understanding these interactions in humans is crucial to the correct use of this new class of agents in the clinic.
Leukemia 1992 Apr
PMID:Recombinant human TNF-alpha stimulates the secretion of granulocyte colony-stimulating factor in vivo. 137 4

Characteristics of hemopoietic-supportive (MS-1 and MS-5) and non-supportive (MS-K) cell lines were compared. Supportive cells adhered to hemopoietic stem cells and produced granulocyte-macrophage colony-stimulating factor (GM-CSF), whereas non-supportive cells did not adhere to hemopoietic cells and only produced macrophage colony-stimulating factor. Both cell lines produced substantial levels of IL-6 and steel factor (SLF) which is reportedly a stem-cell factor. Northern blot analysis revealed that SLF but neither c-kit nor interleukin 3 (IL-3) mRNA was detectable in these cell lines, although IL-3-like activity was found in the supernatant of MS-5 cell culture. These observations suggest that the hemopoietic-supportive function of stromal cells may reside in adherence of stem cells, and production of GM-CSF probably in combination with SLF. SLF may be transferred from stromal cells directly to stem cells through adhesion of stem cells to supportive stromal cells.
Leukemia 1992 May
PMID:Characterization of murine hemopoietic-supportive (MS-1 and MS-5) and non-supportive (MS-K) cell lines. 137 98

Gamma irradiation of plateau-phase clonal bone marrow stromal cell lines produces factor-independent growth of cocultivated clonal interleukin-3/granulocyte-macrophage colony-stimulating factor-dependent hematopoietic progenitor cell lines. The process is associated with three biologic changes including: (i) adherence of hematopoietic cells to stromal cells forming 'cobblestone islands'; (ii) an intermediate stage [during which the cells show proliferation in suspension in the presence in leukemogenic stromal factor (LSF), a factor similar to macrophage colony-stimulating factor (M-CSF) released by irradiated stromal cells, and transient hematopoietic cell surface expression of MAC-1, and c-fms (M-CSF receptor)]; and (iii) a third stage of factor-independence. A monoclonal antibody to M-CSF receptor inhibited proliferation of intermediate stage but not all factor-independent cell subclones. In the present studies, a subclonal factor-independent malignant subline of FDC-P1JL26 derived by cocultivation with gamma-irradiated stromal cells as well as the parent clone and intermediate stage cells were shown to express significant levels of M-CSF polyA+ mRNA and M-CSF of at least two sizes (23 and 15 kDa) as detected by 35S-methionine labelling and immunoprecipitation with polyclonal anti-M-CSF antiserum. There was no significant difference in intracellular M-CSF protein size between cells at each of the three stages of biologic change. This M-CSF was not detected on the cell surface by fluorescence-activated cell sorting (FACS). In contrast, c-fms expression at the cell surface was detected by FACS analysis and c-fms polyA+ mRNA was only detected during the intermediate stage of induction of factor-independence. FDC-P1JL26 parent cells, the subclone stimulated by LSF, and the factor-independent subclone, showed little or no detectable autophosphorylation of the c-fms receptor at tyrosine. There was no detectable rearrangement of the M-CSF or c-fms genes by Southern analysis between clonal lines during the three stages. While we cannot rule out an autocrine mechanism or mutated c-fms receptor mechanism, the data also suggest that evolution of hemopoietic cell factor-independence during cocultivation with irradiated stromal cells may involve a mechanism distal to the c-fms receptor/M-CSF interaction.
Leukemia 1992 Jul
PMID:Expression of M-CSF and its receptor (C-FMS) during factor-independent cell line evolution from hematopoietic progenitor cells cocultivated with gamma irradiated marrow stromal cell lines. 138 39

We have recently reported that normal long-term marrow cultures (LTMC) treated with recombinant human macrophage colony-stimulating factor (rhCSF-1), as well as LTMC from patients with acute myelogenous leukemia (AML), produce a soluble activity capable of inhibiting hemopoietic colony formation in semisolid cultures. In the present study, we have found that such an activity is produced, both in normal and AML LTMC, by an adherent, nonfibroblastic cell population (most likely macrophages), and also by blast cells developed in AML LTMC. The presence of the inhibitory activity correlated with increased levels of tumor necrosis factor (TNF) in the culture supernatants. Part of the activity (30%) produced in rhCSF-1-treated normal LTMC was neutralized in colony assays by anti-TNF alpha monoclonal antibody. In contrast, the soluble inhibitory activity from AML LTMC was completely neutralized by anti-TNF alpha. However, addition of anti-TNF alpha (every 72 h, from day 0 to 21, at 125 ng/ml) to AML LTMC resulted in only partial neutralization of the inhibitory activity, indicating that production of TNF alpha is just one of the mechanisms by which normal hemopoiesis is inhibited in AML LTMC, and that other factors are involved in this process. In keeping with this idea, we found very high levels of prostaglandin E, a hemopoietic inhibitor, in the supernatant of cultures that contained the soluble inhibitory activity. Interestingly, rhCSF-1 showed opposite effects on TNF production in normal (up-regulation) and AML (down-regulation) LTMC, which suggests the presence of functionally abnormal, leukemia-derived macrophages in AML LTMC.
Leukemia 1992 Nov
PMID:Production of tumor necrosis factor-alpha in human long-term marrow cultures from normal subjects and patients with acute myelogenous leukemia: effect of recombinant macrophage colony-stimulating factor. 143 97

DNA methylation belongs to the multilevel genetic control system regulating differentiation processes and gene expression. The extent to which DNA methylation contributes to the differentiation of hematopoietic cells is elusive. In the present study we investigated the methylation state of the c-fms/M-CSF receptor gene in normal human blood cells and tissue macrophages. The methylation pattern of the c-fms gene as detected by isoschizomeric restriction analysis with MspI/HpaII showed only slight interindividual variations in normal donors, whereas constant differences were found between granulocytes and monocytes from the same donor. The second intron of the c-fms gene contains several CpG loci which were found to be hypomethylated on both alleles in monocytes and tissue macrophages. By contrast, these positions were methylated in granulocytes and lymphocytes that did not express the c-fms gene. In comparison to monocytes alveolar and peritoneal macrophages revealed an enhanced demethylation. There were constant differences in c-fms gene methylation between alveolar and peritoneal macrophages with a higher degree of demethylation in alveolar macrophages. We conclude that c-fms gene demethylation is involved in the differentiation of monocytes and macrophages from immature precursors and that the demethylation of lineage-specific growth factor receptor genes might provide an important step in lineage commitment of hematopoietic cells.
Leukemia 1992 May
PMID:Lineage-specific methylation of the c-fms gene in blood cells and macrophages. 159 6

The human factor-dependent leukemia cell line UCSD/AML1 contains the t(3;3) (q21;q26) characteristic of the syndrome of acute leukemia with high platelets. The human homologue of the murine leukemia oncogene evi-1 was recently localized to chromosome 3q24-3q28 and transcription of evi-1 is a frequent event in mouse-retrovirus-induced leukemias (17). To determine whether translocations near human 3q24 might induce similar genetic changes, we examined and compared evi-1 and c-myc expression and regulation in UCSD/AML1 cells. Steady-state evi-1 transcripts were detected in UCSD/AML1 and murine leukemia M1 cells, but were not present in HL60 or Namalwa human leukemia cells. Transcription assays showed the evi-1 gene was actively transcribed in UCSD/AML1, but not HL60 nuclei. Evi-1 transcript sizes and half-life were similar in UCSD/AML1 and human HEC-1B carcinoma cells which express evi-1 transcripts, but do not have abnormalities involving chromosome 3. An alternative splice site detected by polymerase chain reaction was present in transcripts from both cell lines. Regulation of evi-1 RNA in UCSD/AML1 cells was similar to that of actin transcripts in response to cycloheximide or phorbol-ester-induced macrophage differentiation. After withdrawal of granulocyte/macrophage colony-stimulating factor (GM-CSF), evi-1, actin, and histone H3 transcripts declined in concert with exit from the cell cycle. Minor differences in rates of recovery were noted for these three genes after GM-CSF restimulation. In contrast, c-myc was expressed at high levels in UCSD/AML1 cells and showed evidence for specific regulation in response to cycloheximide, phorbol ester, and GM-CSF withdrawal and restimulation. These studies suggest the 3q translocation in UCSD/AML1 cells is associated with evi-1 transcription and expression of a potential transforming gene. In contrast to c-myc, evi-1 expression is minimally altered by biologically active chemicals or growth factor stimulation.
Leukemia 1992 May
PMID:Expression and regulation of the evi-1 gene in the human factor-dependent leukemia cell line, UCSD/AML1. 159 10

Exposure of 3 month old SJL/J mice to a single dose of 300 r yielded 15-30% acute myelomonocytic leukemia (AML) development at a mean latency of 1 year. Additional treatment with dexamethasone shortly after irradiation increased leukemia incidence to 50%. All tumors were characterized by a partial deletion of one allele of chromosome 2 and the same deletion was detected in bone marrow and spleen cells of most irradiated mice, irrespective of the development of the disease. The presence of potential leukemic cells (PLC) in mice 4 months after the leukemogenic treatment was confirmed by transplantation studies. In these experiments PLC transition into overt AML seemed to be dependent on their transfer into irradiated recipients. Thus, exposure to 300 r results in the initiation of potential leukemic cells. Experiments were conducted in order to explore the possible role of radiation, cytokines and different hemopoietic growth factors on PLC promotion to overt leukemia. Exposure to 300 r, beside PLC initiation, was found to trigger the production of IL-6 and CSF-1; the additional administration of dexamethasone further increased CSF-1 levels. In vivo administration of CSF-1 into mice carrying radiation-induced PLC was most effective in PLC promotion to overt AML development.
Leukemia 1992
PMID:Multiphase process involved in radiation induced murine AML. 160 7

Acute myelomonocytic leukemia develops in 10-30% of irradiated (300 rad) SJL/J mice, after a lag period of around one year. Additional treatment with dexamethasone shortly after irradiation increased leukemia incidence up to 50%. Experiments were conducted in order to demonstrate the existence of preleukemic cells in irradiated mice and to explore the possible role of dexamethasone, cyclophosphamide, and different hemopoietic growth factors on their promotion to overt leukemia. Transplantation of bone marrow cells from mice exposed to 300 rad plus dexamethasone into appropriate recipients, performed 4-5 months after leukemogenic treatment, resulted in acute myeloid leukemia (AML) development of donor origin in 70% of the recipients. Transfer of fractionated preleukemic bone marrow showed that the highest AML incidence developed in the recipients of fractions enriched in early hemopoietic precursors. The promoting effect of dexamethasone on preleukemic cells was confirmed by demonstrating its similar coleukemogenic effect whether administered within several hours or 130 days after radiation. Treatment with cyclophosphamide shortly after radiation could not replace the dexamethasone effect but was found to be complementary to the coleukemogenic effect of dexamethasone. Early administration of hemopoietic growth factors (starting 14 days after radiation and dexamethasone) showed that colony-stimulating factor (CSF) 1 increased the AML incidence (75%) and reduced its latency. Treatment with recombinant granulocyte-CSF (rG-CSF) had a reduced effect and recombinant granulocyte-macrophage CSF (rGM-CSF) had no promoting effect. However, administration of different factors several months after the leukemogenic treatment revealed that rGM-CSF increased AML incidence (75%) and shortened its latency, whereas rG-CSF and CSF-1 had no effect. In contrast, the late administration of recombinant interleukin 6 reduced AML incidence significantly (23%). The present results indicate that murine radiation induced AML is a multiphase process involving radiation induced preleukemia that can be promoted by different treatments.
Leukemia 1992 Jul
PMID:Initiation and promotion in radiation-induced myeloid leukemia. 162 87

We have previously shown that total T cells derived from lymph nodes (LN) involved by Hodgkin's disease (HD) secrete higher levels of colony-stimulating activity than total T cells present within benign hyperplastic (BH) LN and B-non-Hodgkin's lymphoma (B-NHL) LN, suggesting that T cells with particular properties accumulate in HD LN. To further characterize this T-cell population, we have quantified production of both granulocyte-macrophage colony-stimulating factor (GM-CSF) and macrophage colony-stimulating factor (M-CSF) production in a total of 98 T-cell clones (TCC) derived from CD25+ activated T cells present in HD LN; TCC derived from CD25+ T cells obtained from B-NHL LN(101 TCC), BH LN(95 TCC), and peripheral blood (PBL; 38 TCC) of healthy donors were used as controls. HD LN were characterized by the presence of an elevated number (44%) of TCC producing particularly high titers of both GM-CSF and M-CSF, whereas only a minority of such TCC was found in control groups (10% in B-NHL, 16% in BH, 8% in PBL). These observations support the hypothesis of a selection of T-cell families with particular properties occurring in contact with Reed-Sternberg (RS) cells. According to the biological properties of GM-CSF and M-CSF, it seems reasonable to suggest the involvement of this particular subset of T cells in the granulomatous process, the peripheral blood polynucleosis, and in the paracrine growth of RS cells.
Leukemia 1992 Aug
PMID:Accumulation of T-cell clones producing high levels of both granulocyte-macrophage and macrophage colony-stimulating factors (CSF-1) in lymph nodes involved by Hodgkin's disease. 164 Jul 35

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