There is limited understanding of CD34− hematopoietic cells and the linkage between CD34 antigen expression and cell proliferation. In this study, early CD34− CD38− LIN− (CD34−) cells were purified from mobilized adult peripheral blood and carefully analyzed in vitro for growth and modulation of CD34. Mobilized CD34+CD38− LIN− (CD34+) cells were used for comparison. Expression of CD34, CD38, and LIN antigens was determined, and proliferative responses were assessed with PKH tracking dye, expression of Ki67 antigen, and uptake of pyronin Y. Suspension cultures of adult CD34− cells generated CD34+ cells and progenitors for >8 weeks. Stromal cultures demonstrated the presence of long‐term culture‐initiating cells within the CD34− fraction. While CD34− cells were slower to initiate growth than the CD34+ cells were, no significant difference in hematopoietic cell output was found. Upon cultivation of CD34− cells, CD34 antigen appeared within 48 hours but was restricted to those cells that had initiated growth. Surprisingly, CD34+ precursors lost CD34 expression in culture if they remained in G0 for more than 2 days. Those cells later regained expression of CD34 antigen upon initiation of growth. Comparison of cells that did or did not rapidly modulate CD34 antigen revealed no differences in long‐term growth potential. In conclusion, in vitro expression of CD34 by CD34− and CD34+ populations is tightly linked to cellular proliferation. In this culture system, expression of CD34 antigen by LIN− cells constitutes an early hallmark of growth. Measurement of CD34 expression by LIN− cells in expansion culture underestimates the total content of hematopoietic cells.
Flt3 ligand (FL) has been proposed as a possible modulator of early hematopoietic cell growth. The purpose of this study was to analyze the impact of FL on ex vivo expansion of hematopoietic cells obtained from adult donors. We sought to precisely identify hematopoietic populations responsive to FL and to quantitate the ability of FL to enhance the survival and/or proliferation of early hematopoietic precursors in a stroma-free culture system. Towards that end, four CD34+ subsets were isolated and their response to FL was characterized. In methylcellulose, FL significantly increased colony formation by CD34+ CD38dim cells but not CD34+ CD38+ cells. In suspension culture, the enhancement of cell expansion by FL was 10 times greater with the CD34+ CD38dim fraction than the CD34+ CD38+ fraction. FL stimulated the generation of colony-forming unit–granulocyte-macrophage (CFU-GM) from the CD34+CD38dim fraction by 14.5- ± 5.6-fold. To determine if CD34+ CD38dim cells responded uniformly to FL, the population was subdivided into a CD34+ CD38dim CD33dim HLA-DR+ (HLA-DR+) fraction and a CD34+ CD38dim CD33dim HLA-DRdim (HLA-DRdim) fraction. FL was far more effective at stimulating cell and progenitor growth from the HLA-DR+ fraction. To determine if FL enhanced or depleted the number of precommitted cells in expansion culture, CD34+ CD38dim and HLA-DR+ fractions were incubated in liquid culture and analyzed by flow cytometry. Inclusion of FL enhanced the absolute number of primitive CD34+ CD33dim cells and CD34+ HLA-DRdim cells after 5 to 12 days of cultivation. To confirm immunophenotypic data, the effect of FL on long-term culture-initiating cells (LTCIC) was determined. After 2 weeks of incubation of CD34+ CD38dim or HLA-DR+ cultures, LTCIC recoveries were significantly higher with FL in 5 of 6 trials (P < .05). For HLA-DR+ cells, LTCIC recoveries averaged 214% ± 87% of input with FL and 24% ± 16% without FL. In contrast, HLA-DRdim LTCIC could not be maintained in stroma-free culture. We conclude that less than 10% of CD34+ cells respond vigorously to FL and that those cells are contained within the HLA-DR+ fraction. FL stimulates the expansion of total cells, CD34+ cells, and CFU-GM and enhances the pool of early CD34+ CD33dim cells, CD34+ HLA-DRdim cells, and LTCIC. These data indicate that it is possible to expand hematopoietic progenitors from adult donors without losing precursors from the precommitted cell pool.
The bone marrow microenvironment consists of stromal cells and extracellular matrix components which act in concert to regulate the growth and differentiation of hematopoietic stem cells. There is little understanding of the mechanisms which modulate the regulatory role of stromal cells. This study examined the hypothesis that mesenchymal growth factors such as basic fibroblast growth factor (bFGF) and epidermal growth factor (EGF) modulate stromal cell activities and thereby influence the course of hematopoiesis. Both bFGF and EGF were potent mitogens for marrow stroma. However, both factors proved to be inhibitory to hematopoiesis in primary long-term marrow cultures. Inhibition was also observed when hematopoietic cells and bFGF or EGF were added to subconfluent irradiated stromal layers, demonstrating that the decline of hematopoiesis was not due to overgrowth of the stromal layer. Loss of hematopoietic support in bFGF and EGF was dose-dependent. Removal of bFGF and EGF permitted stromal layers to regain their normal capacity to support hematopoiesis. In stroma-free long-term cultures, neither factor affected CFU-GM expansion. Basic FGF slightly enhanced granulocyte-macrophage colony forming unit (CFU-GM) cloning efficiency in short-term agarose culture. Basic FGF did not reduce the levels of interleukin-6 (IL-6), GM-CSF, or G-CSF released by steady state or IL-1-stimulated stroma. Similarly, the constitutive levels of steel factor (SF) mRNA and protein were not affected by bFGF. Basic FGF did not alter the level of TGF-beta 1 in stromal cultures. We conclude that bFGF and EGF can act as indirect negative modulators of hematopoietic growth in stromal cultures. The actual mediators of regulation, whether bound or soluble, remain to be identified.
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