Csf-1 Control of C-Fms Expression in Normal Human Bone-Marrow Progenitors

We have previously shown (Zhou et al: Blood, 72:1870, 1988) that IL3, added with low concentrations of CSF-1 (I ng/ml) to normal human CD34+ enriched cells, promoted the development of various types of colonies including those containing immature monocytes. However, when high concentrations of CSF-1 (20 ng/ml) were added alone or together with IL3, smaller colonies with mature macrophages were found. Here we show by in situ hybridization that IL3 allows the development, from CD34+ cells, of a subpopulation of immature progenitors which express the CSF-1 receptor (c-fms) mRNA. The expression of c-FMS protein was also substantiated by immunocytochemical studies using anti-c-fms antibody. The percentage of c-fms positive cells peaked at day 7 and began to decrease thereafter. When anti-CSF-1 antibodies were included in the culture, the decrease in c-fms mRNA after day 7 was abrogated. This indicated that endogenous CSF-1 was produced as CD34+ cells developed into monocytes or progenitors of monocytes and that CSF-1 modulates c-fms expression. We further demonstrated that when a high dose of CSF-1 (20 ng/ml) was added at day 7 to IL3-stimulated CD34+ cells, a rapid down-regulation of c-fms mRNA and protein was seen. No down-regulation was observed with low concentration of CSF-1 (1 ng/ml). The possibility that different concentrations of CSF-1 could modulate the development of monocytic progenitors is discussed

C-Fos Messenger-Rna Constitutive Expression by Mature Human Megakaryocytes

By in situ hybridization with a c-fos probe, we have shown that human bone marrow megakaryocytes cultured in the presence of 20% aplastic anemia plasma constitutively express c-fos mRNA. At day 0, megakaryocytes are mostly immature and only 3% of them are labeled. The number of labeled cells reached 23% after 12 days of culture. Interleukin 3 (IL-3) and IL-6 added together at day 10 further increased this number to 31% 2 days later. Mature labeled megakaryocytes were more numerous and more strongly labeled than immature ones. These results suggest that c-fos could play a role in megakaryocytic terminal differentiation, either in the polyploidization or in the thrombopoietic function unique to these cells

Early Cd34(High) Cells Can Be Separated Into Kithigh Cells in Which Transforming Growth-Factor-Beta (Tgf-Beta) Down-Modulates C-Kit and Kitlow Cells in Which Anti-Tgf-Beta Upmodulates C-Kit

We have previously shown that early human CD34(high) hematopoietic progenitors are maintained quiescent in part through autocrine transforming growth factor-beta 1 (TGF-beta 1). We also demonstrated that, in the presence of interleukin-3, interleukin-6, granulocyte colony-stimulating factor, and erythropoietin. TGF-beta 1 antisense oligonucleotides or anti-TGF-beta serum have an additive effect with KIT ligand (Steel factor [SF]), which suggests that they control different pathways of regulation in these conditions. This finding also suggests that autocrine TGF-beta 1 might suppress c-kit expression in primitive human hematopoietic progenitors. We have now distinguished two subpopulations of CD34(high) cells. One subpopulation expresses a c-kit mRNA that can be downmodulated by exogenous TGF-beta 1 within 6 hours. Another subpopulation of early CD34(high) cells expresses a low or undetectable level of c-kit mRNA, but its expression can beupmodulated within 6 hours by anti-TGF-beta. These effects disappear 48 hours after induction and cannot be maintained longer than 72 hours, even if TGF-beta 1 or anti-TGF-beta serum are added every day. Similar kinetics, although delayed, are observed with KIT protein expression. On the contrary, no specific effect of TGF-beta 1 was observed on c-fms, GAPDH, and transferrin receptor gene expression in these early progenitors. These results clarify the complex interaction between TGF-beta 1 and SF in normal early hematopoietic progenitors. SF does not switch off the TGF-beta 1 inhibitory pathway. Autocrine TGF-beta 1 appears to maintain these cells in a quiescent state, suppressing cell division by downmodulating the receptor of SF, a key cytokine costimulator of early progenitors. (C) 1995 by The American Society of Hematology

Purification and Release From Quiescence of Umbilical-Cord Blood Early Progenitors Reveal Their Potential to Engraft Adults

Steel factor (SF) increases the frequency of colony formation by CD34(+) CD38(-) cycling cells, but it does not reverse the effect of an autocrine production of transforming growth factor (TGF)-beta(1) by early progenitors of the stem cell compartment. We have used optimal culture conditions supplemented with SF and anti-TGF-beta serum to estimate the proliferative capacity and ability to generate early progenitors in long-term cultures of bone marrow and umbilical cord blood cells. We estimate that the CD34(+) CD38(-) cells from a typical umbilical cord blood sample produce equivalent numbers of granulocyte erythrocyte macrophage megakaryocyte colony-forming units (CFU), twice as many granulocyte-macrophage (GM) CFU, and three times as many erythroid burst-forming units as the same population from an average bone marrow sample used in adult transplantation. These results suggest that umbilical cord blood is a suitable source of cells for adult transplantation

Release from quiescence of CD34+ CD38- human umbilical cord blood cells reveals their potentiality to engraft adults.

Using optimal culture conditions in which the transforming growth factor beta 1 (TGF-beta 1) inhibitory loop has been interrupted by antisense TGF-beta 1 oligonucleotides or anti-TGF-beta serum, we have compared the proliferative capacities and the abilities of the CD34+ CD38- cell populations from bone marrow and umbilical cord blood to generate early progenitors in long-term cultures. The CD34+ CD38- fraction of umbilical cord blood accounts for 4% of the CD34+ fraction compared to only 1% in bone marrow, indicating that umbilical cord blood may be relatively enriched in stem cells. We estimate that the CD34+ CD38- cells from a typical umbilical cord blood sample produce equivalent numbers of colony-forming units (CFU)-granulocyte/erythrocyte/macrophage/megakaryocyte, twice as many CFU-granulocyte/macrophage (GM) and 3 times as many burst-forming units-erythroid as the same population from an average bone marrow sample used in adult transplantation. In addition, the colonies resulting from the umbilical cord blood samples were significantly larger than those from bone marrow, indicating a greater growth potential. However, the content of later progenitors, which may be important for short-term reconstitution, was less in umbilical cord blood-derived than in bone marrow-derived cell preparations, as estimated by a 4-fold lower production of CFU-GM in long-term cultures of CD34+ CD38+ cells. This deficit is partially compensated by the higher growth capacity of the resulting CFU-GM. These studies suggest that umbilical cord blood is a suitable source of cells for adult transplantation