Proto-oncogene expression during early myeloid differentiation of normal peripheral blood progenitor cells

Quantification of damage due to low-dose radiation exposure in mice: construction and application of a biodosimetric model using mRNA indicators in circulating white blood cells

Biodosimetry, the measurement of radiation damage in a biologic sample, is a reliable tool for increasing the accuracy of dose estimation. Although established chromosome analyses are suitable for estimating the absorbed dose after high-dose irradiation, biodosimetric methodology to measure damage following low-dose exposure is underdeveloped. RNA analysis of circulating blood containing radiation-sensitive cells is a candidate biodosimetry method. Here we quantified RNA from a small amount of blood isolated from mice following low-dose body irradiation (<0.5 Gy) aimed at developing biodosimetric tools for situations that are difficult to study in humans. By focusing on radiation-sensitive undifferentiated cells in the blood based on Myc RNA expression, we quantified the relative levels of RNA for DNA damage-induced (DDI) genes, such as Bax, Bbc3 and Cdkn1a. The RNA ratios of DDI genes/Myc in the blood increased in a dose-dependent manner 4 h after whole-body irradiation at doses ranging from 0.1 to 0.5 Gy (air-kerma) of X-rays, regardless of whether the mice were in an active or resting state. The RNA ratios were significantly increased after 0.014 Gy (air-kerma) of single X-ray irradiation. The RNA ratios were directly proportional to the absorbed doses in water ranging from 0.1 to 0.5 Gy, based on gamma-irradiation from (137)Cs. Four hours after continuous irradiation with gamma-rays or by internal contamination with a beta-emitter, the increased RNA ratios resembled those following single irradiation. These findings indicate that the RNA status can be utilized as a biodosimetric tool to estimate low-dose radiation when focusing on undifferentiated cells in blood.

Induction of the fms proto-oncogene product in HL-60 cells by vitamin D: a flow cytometric analysis

Agents which induce monocytic characteristics in HL-60 human acute promyelocytic leukemia cells induce mRNA for the fms proto-oncogene, which encodes the receptor for M-CSF. Previous studies of fms expression in HL-60 cells have characterized chiefly induction by phorbol esters of fms mRNA. Our studies of fms expression in HI-60 cells have characterized induction by vitamin D3 of the fms protein. We have used flow cytometry to correlate fms antigen with a monocyte-specific differentiation antigen recognized by antibody MO2 (CD14), with DNA content, and with the nuclear antigen Ki-67, a marker of cell cycling. HL-60 cells were cultured with or without 1 microM vitamin D for 7 days. fms antigen was found on 42 +/- 5.8% of the cells cultured without vitamin D, but on 63 +/- 4.3% of the cells cultured with vitamin D. MO2 binding was detected on only 2 +/- 0.5% of the cells without vitamin D, but on 59 +/- 9% with vitamin D. Cells cultured with vitamin D that were fms-positive were also predominantly (83%) MO2-positive. Analysis of DNA content, measured by propidium iodide staining, showed that 57 +/- 1.5% of cells cultured without vitamin D, but 93 +/- 0.5% of cells cultured with vitamin D, were in the G0/G1 cell cycle phase. Analysis of nuclear antigen Ki-67 revealed that, of the vitamin D-treated cells that were fms-positive, a significant proportion (37%) were still cycling. We conclude that (1) fms is demonstrable on some uninduced HL-60 cells, (2) when HL-60 cells are induced to develop monocytic characteristics by vitamin D, fms induction is part of the program for monocytic differentiation that includes MO2 expression, yet (3) some induced cells expressing fms are still cycling.

Studies of the geographic patterns of c-myc expression in bone marrow

C-myc expression was studied semi-quantitatively in bone marrow biopsies obtained from normal individuals, patients with non-malignant haematological disorders and patients with various haematological malignancies. In normal bone marrow and in the bone marrow of patients with non-malignant haematological disorders, cells containing c-myc protein are present in small clones (average 7 +/- 2.5 cells/clone) located in the centre of the histotopographic region of the biopsy. In contrast, c-myc-containing cells are diffusely distributed in the bone marrow of patients with acute myelogenous leukaemia (AML). In the marrow of patients with myelodysplastic syndromes evolving to AML and in patients with AML in early relapse, the clones of cells containing c-myc are larger than those present in normal marrows (average clone size = 17.5 +/- 3.5 cells). Additionally, the proportion of the cells in normal bone marrow which express c-myc protein is less than that present in AML marrows (23.3 +/- 10.17 v. 60.2 +/- 6.17) and the intensity of staining is also less. Non-Hodgkin's lymphoma patients with bone marrow involvement had distribution of c-myc positive cells similar to those with leukaemic infiltration.

A liquid culture method for the in vitro growth of hemopoietic progenitor cells from normal human adult peripheral blood allowing for analysis by multiparameter flow-cytometry

A liquid culture method has been developed allowing for the in vitro growth of peripheral blood-derived hemopoietic progenitor cells of myeloid, erythroid, monocytic and megakaryocytic lineages. Adherent cell- and CD21-positive cell-depleted PBMC from normal subjects have been cultured in the presence of rhEPO, rhGM-CSF or rhIl-3. Culturing cells in liquid cultures and in plasma clots, a similar dose-response was observed for granulocytic cells/liquid culture and granulocytic colonies/plasma clot with rhGM-CSF, and also for erythroid cells/liquid culture and erythroid colonies/plasma clot with rhEPO. Comparing serum- liquid cultures to serum+ liquid cultures, the ratio of CD13+ cells to CD15+ cells was higher in serum- cultures, indicating a maturation arrest of myecloid cells with serum deprivation. Using dual-colour flow-cytometry, cell-cycle analysis of CD13+ cells, comparing the effects of rhGM-CSF to those of rhIl-3, have been performed. The liquid culture method promises to be a useful tool for the study of in vitro differentiation and proliferation of hemopoietic progenitor cells.