Verfaillie C M
Department of Medicine, University of Minnesota, Minneapolis.
Blood. 1993 Oct 1;82(7):2045-53.
We have recently shown that conservation and differentiation of primitive human hematopoietic progenitors in in vitro long-term bone marrow cultures (LTBMC) occurs to a greater extent when hematopoietic cells are grown separated from the stromal layer than when grown in direct contact with the stroma. This finding suggests that hematopoiesis may depend mainly on soluble factors produced by the stroma. To define these soluble factors, we examine here whether a combination of defined early-acting cytokines can replace soluble stroma-derived biologic activities that induce conservation and differentiation of primitive progenitors. Normal human Lineage-/CD34+/HLA-DR- cells (DR-) were cultured either in the absence of a stromal layer ("stroma-free") or in a culture system in which DR- cells were separated from the stromal layer by a microporous membrane ("stroma-noncontact"). Both culture systems were supplemented three times per week with or without cytokines. These studies show that culture of DR- cells for 5 weeks in a "stroma-free" culture supplemented with a combination of four early acting cytokines (Interleukin-3 [IL-3], stem cell factor [SCF], leukemia-inhibitory factor [LIF], and granulocyte colony-stimulating factor [G-CSF]) results in a similar cell expansion as when DR- cells are cultured in "stroma-noncontact" cultures supplemented with the same cytokines. However, generation of committed progenitors and conservation of the more primitive long-term bone marrow culture initiating cells (LTBMC-IC) was far superior in "stroma-noncontact" cultures supplemented with or without IL-3 than in "stroma-free" cultures supplemented with IL-3 alone or a combination of IL-3, LIF, G-CSF, and SCF. These studies indicate that human BM stroma produces soluble factors that can either alone or in synergy with defined cytokines (1) conserve primitive LTBMC-IC, (2) induce early differentiation of a fraction of the primitive progenitors, and (3) prevent their terminal differentiation. We show here that these stroma-derived factors are not likely to be the known early acting cytokines IL-3, SCF, LIF, or G-CSF. Characterization of the stroma-derived factor(s) may have important implications for clinically relevant studies, such as in vitro stem cell expansion in cancer treatment and gene therapy.
我们最近发现,在体外长期骨髓培养(LTBMC)中,原始人类造血祖细胞的保存和分化在造血细胞与基质层分离培养时比与基质直接接触培养时更为显著。这一发现表明,造血过程可能主要依赖于基质产生的可溶性因子。为了确定这些可溶性因子,我们在此研究特定的早期作用细胞因子组合是否能够替代基质衍生的可溶性生物活性物质,这些活性物质可诱导原始祖细胞的保存和分化。将正常人谱系阴性/CD34阳性/HLA-DR阴性细胞(DR-)在无基质层的条件下培养(“无基质”),或在一种培养系统中培养,在该系统中DR-细胞通过微孔膜与基质层分离(“基质非接触”)。两种培养系统每周补充三次细胞因子,添加或不添加细胞因子。这些研究表明,在添加了四种早期作用细胞因子(白细胞介素-3 [IL-3]、干细胞因子 [SCF]、白血病抑制因子 [LIF] 和粒细胞集落刺激因子 [G-CSF])组合的“无基质”培养中,将DR-细胞培养5周所产生的细胞扩增与在添加相同细胞因子的“基质非接触”培养中培养DR-细胞的情况相似。然而,在添加或不添加IL-3的“基质非接触”培养中,定向祖细胞的生成以及更原始的长期骨髓培养起始细胞(LTBMC-IC)的保存远优于仅添加IL-3或添加IL-3、LIF、G-CSF和SCF组合的“无基质”培养。这些研究表明,人类骨髓基质产生的可溶性因子可单独或与特定细胞因子协同作用:(1)保存原始的LTBMC-IC;(2)诱导一部分原始祖细胞的早期分化;(3)防止它们的终末分化。我们在此表明,这些基质衍生因子不太可能是已知的早期作用细胞因子IL-3、SCF、LIF或G-CSF。基质衍生因子的特性鉴定可能对临床相关研究具有重要意义,例如癌症治疗和基因治疗中的体外干细胞扩增。
